Calpains are a family of 15 calcium-activated cysteine proteases that have emerged as potential antimetastatic targets in breast cancer. Calpain-1 and calpain-2 are ubiquitously expressed heterodimers composed of unique catalytic subunits (encoded by Capn1 and Capn2, respectively) and a common regulatory subunit (encoded by Capns1). Genetic disruption of Capns1 abolishes calpain-1 and calpain-2 activity. Using CRISPR-Cas9 mediated Capns1 knockout, we validated calpains-1/2 as promising therapeutic targets in a mouse model of mammary carcinoma. Capns1 knockout impaired cell invasion by 53 ± 10% in vitro and reduced lung metastasis by 68 ± 12% in an orthotopic engraftment mouse model.
","acknowledgements":"We would like to thank Chris Hall, Jeffrey Mewburn, Dr. Changnian Chi and Dr. Victoria Hoskin for technical assistance.
","authors":[{"affiliations":["Queen's University"],"departments":["Pathology and Molecular Medicine"],"credit":["conceptualization","dataCuration","formalAnalysis","methodology","visualization","writing_originalDraft"],"email":"danielle.harper@queensu.ca","firstName":"Danielle ","lastName":"Harper","submittingAuthor":true,"correspondingAuthor":true,"equalContribution":false,"WBId":null,"orcid":"0009-0009-1184-4923"},{"affiliations":["Queen's University"],"departments":["Pathology and Molecular Medicine"],"credit":["conceptualization","dataCuration","methodology","writing_reviewEditing"],"email":"ivan.shapovalov@queensu.ca","firstName":"Ivan ","lastName":"Shapovalov ","submittingAuthor":false,"correspondingAuthor":false,"equalContribution":false,"WBId":null,"orcid":null},{"affiliations":["Queen's University"],"departments":["Pathology and Molecular Medicine"],"credit":["dataCuration"],"email":"17sec6@queensu.ca","firstName":"Samantha ","lastName":"Cockburn","submittingAuthor":false,"correspondingAuthor":false,"equalContribution":false,"WBId":null,"orcid":null},{"affiliations":["Queen's University"],"departments":["Pathology and Molecular Medicine"],"credit":["dataCuration"],"email":"20ara4@queensu.ca","firstName":"Anya ","lastName":"Aaron","submittingAuthor":false,"correspondingAuthor":false,"equalContribution":false,"WBId":null,"orcid":null},{"affiliations":["Queen's University"],"departments":["Pathology and Molecular Medicine"],"credit":["dataCuration","methodology","resources"],"email":"yg2@queensu.ca","firstName":"Yan ","lastName":"Gao","submittingAuthor":false,"correspondingAuthor":false,"equalContribution":false,"WBId":null,"orcid":null},{"affiliations":["Queen's University"],"departments":["Pathology and Molecular Medicine",""],"credit":["conceptualization","fundingAcquisition","supervision","writing_reviewEditing"],"email":"greerp@queensu.ca","firstName":"Peter A","lastName":"Greer","submittingAuthor":false,"correspondingAuthor":false,"equalContribution":false,"WBId":null,"orcid":null}],"awards":[{"awardId":"PJT-166062","funderName":"Canada Institutes of Health Research (Canada)","awardRecipient":"Peter A Greer"}],"conflictsOfInterest":"The authors declare that there are no conflicts of interest present.
","dataTable":{"url":null},"extendedData":[],"funding":"This study was funded by a Canadian Institutes of Health Research project grant (PJT-166062) to P.A.G, and a Dean's Doctoral Award to DH.
","image":{"url":"https://portal.micropublication.org/uploads/9b182d269de237c83ba45a8736194d88.png"},"imageCaption":"A) Validation of genetic calpain-1/2 disruption in AC2M2 cells by immunoblotting (upper) and casein zymography (lower). (B) Relative distance invaded from 3D AC2M2 spheroids at 48 (left) and 72 hours (right). (C) Representative images of spheroids at 48 hours. (D) Resect-and-wait orthotopic engraftment metastasis model workflow (E) Relative tumour growth rates in vivo. (F) Lung metastatic burden 10 days post tumour resection. (G) Representative whole mount images of lungs with GFP signal corresponding to metastatic lesions.
Capns1 knockout impairs AC2M2 invasion in vitro and metastatic progression in vivo
","methods":"Genetic manipulation of Capns1
CRISPR-Cas9 mediated knockout (KO) of mouse Capns1 in AC2M2 cells was achieved by transduction with lentivirus produced in HEK293T cells from psPAX2 and pMD.2G, and lentiCRISPRv2-Neo plasmids as previously described (Sanjana et al., 2014). The gene targeting guide RNA (m-Capns1 gRNA) sequence (5’-gtgctcggaggcctgatcag-3’) was cloned into the BsmBI restriction site of lentiCRISPRv2-Neo lentiviral shuttle vector (Primers, Forward: 5’-caccgtgctcggaggcctgatcag-3’, Reverse: 5’-aaacctgatcaggcctccgagcac -3’). Neomycin-selected transduced cells were diluted in 96 well plates to produce monoclonal populations of Capns1 KO AC2M2s. Using AC2M2 cDNA as a template, Capns1 was amplified by PCR and cloned into the PmeI restriction site of the pMSCV-puro retroviral vector (Primers, Forward: FW: 5’-cgacgtttaaactcatgttcttggtgaattcgttcttg-3’, Reverse: 5’- gtccgtttaaacactcagggtgcagcaaggtgtggcatgttgagc -3’). Rescue was achieved by transducing Capns1 KO AC2M2 cells with retrovirus produced in HEK23T cells transfected with pCL-Eco and pMSCV-Puro-Capns1. Calpain-1/2 protein expression and activity were assessed via immunoblotting and casein zymography, as previously described (Harper et al., 2025).
Spheroid Invasion
One x 104 GFP+ AC2M2 cells were seeded into each well of a round-bottom cell-repellent 96-well plate (Greiner Bio-One, Catalogue #: 650970). After 72 hours, spheroids were collected using a p1000 pipette with sterile cut tips and resuspended in 25% Matrigel (Corning; Catalogue #: 354230) in complete DMEM. Spheroids were plated on Ibidi chamber slides (Ibidi; Catalogue #: 80426) and incubated at 37oC for 30 minutes to allow the new layer of Matrigel to solidify. An initial image (time=0) of each spheroid was captured using an EVOS m7000 microscope on the GFP channel. Spheroids were subsequently imaged at 24, 48 and 72 hours. Quantification of invasion was performed in FIJI (Schindelin et al., 2012). The average distance invaded was estimated by calculating the mean of 4 measurements from the edge of each spheroid to the furthest point on the invasive front at 0o, 90o, 180o, and 270o positions. The total area invaded was calculated by subtracting the area of the spheroid (π x spheroid radius2) from the area contained within the borders of the invasive front [π x (spheroid radius + average distance invaded)2]. Within each biological replicate, data were normalized to the WT control. Statistical analyses were performed for each time point on biological replicate means using ordinary one-way ANOVA with Tukey’s multiple-comparisons test in Prism GraphPad 10.
Resect-and-wait spontaneous metastasis
Resect-and-wait experiments for spontaneous lung metastasis were performed as previously described (Harper et al., 2025; Hoskin et al., 2022). All experiments involving the use of animals were performed in accordance with the Canadian Council on Animal Care (CCAC) guidelines and with the approval of Queen’s University Animal Care Committee.
GFP+ AC2M2 cells were prepared in a 1:1 ratio of cell suspension (in PBS) to Matrigel. Using a 50µL Hamilton syringe (Hamilton; Catalogue #: 80500), 7500 AC2M2 cells were injected into the 4th mammary fat pad of 8-12 week old female BalbC-Rag2-/-/IL2Rgc-/- mice (Colucci et al., 1999). Tumour growth was monitored beginning on day 10 using circle-template-based estimates (Staedtler; Catalogue #: 977501) and tumours were resected by recovery surgery after reaching equivalent sizes (500mm3, ~18-22 days post engraftment). Mice were euthanised 10 days post-tumour resection and lungs were harvested for imaging on the GFP Ex/Em channel on the EVOS m7000 microscope (ThermoFisher Scientific, Catalogue #: AMF7000). Anterior and posterior images of the lungs were captured, and the metastatic burden was calculated by determining the % lung area occupied by GFP+ signal. For each experimental replicate, metastatic burden was normalised to WT control. Data was analysed using ordinary one-way ANOVA with Tukey’s multiple comparisons test in Prism GraphPad 10.
","reagents":"","patternDescription":"Triple-negative breast cancer (TNBC) is a heterogenous breast cancer subtype characterized by a lack of estrogen receptor (ER), progesterone receptor (PR), and human epidermal growth factor receptor 2 (HER2) expression. Across all breast cancer subtypes, progression from localized to metastatic disease is associated with 76.8% reduction in 5-year survival (Ellison & Saint-Jacques, 2023). The deadly consequences of metastatic progression are exacerbated for TNBC patients, with 5-year survival for stage IV disease at just 12.1% (Surveillance Research Program, 2025). This underscores an urgent need for therapies which can prevent or slow the metastatic progression of TNBC.
A growing number of preclinical and translational studies have implicated calpain proteases in cancer (Shapovalov et al., 2022; Storr et al., 2011). Human calpains are a family of 15 calcium-activated cysteine proteases (Ono & Sorimachi, 2012). The two most widely studied isoforms, calpain-1 and calpain-2 (referred to as calpain-1/2), are ubiquitously expressed heterodimers consisting of a unique large catalytic subunit, encoded by CAPN1 or CAPN2 genes respectively, and an obligate common regulatory subunit, encoded by CAPNS1 (Wheelock, 1982). Genetic disruption of CAPNS1 is associated with a loss of calpain-1 and calpain-2 activity (Arthur et al., 2000). At present, there are no clinically approved calpain inhibitors available. While several active-site directed calpain inhibitors have been developed, they produce off-target effects on other proteases and lack specificity for calpains, let alone individual calpain isoforms (Ono et al., 2016). We have employed genetic approaches to validate calpain-1/2 as promising therapeutic targets in TNBC.
We previously reported that genetic disruption of CAPNS1 impaired human MDA-MB-231 TNBC cell migration in vitro and attenuated lung metastasis in an orthotopic xenograft mouse model (Harper et al., 2025). Here, we demonstrate that CRISPR-Cas9 mediated knockout of Capns1 produces similar effects in an allogeneic mouse model using the AC2M2 murine mammary carcinoma cell line. AC2M2 is a highly metastatic variant of the TNBC-like SP1 mammary adenocarcinoma cell line derived in the laboratory of Dr. Bruce Elliott at Queen’s University (Elliott et al., 2005). Following validation of CRISPR-Cas9 mediated Capns1 knockout (KO) and gene add-back rescue (RES) by immunoblotting and casein zymography (Figure 1A), we employed a spheroid invasion assay to a observe how loss of calpain-1/2 activity affects 3D-invasion. Lung metastasis was evaluated in vivo using an orthotopic engraftment, resect-and-wait-mouse model.
To assess the impact of Capns1 KO on the ability of AC2M2 cells to invade the extracellular matrix, WT, Capns1 KO, and Capns1 RES AC2M2 spheroids were established in cell-repellent, round-bottom 96-well plates, and subsequently embedded into a 25% Matrigel matrix on an Ibidi chamber slide. As illustrated in Figure 1 panels B and C, Capns1 KO was associated with a statistically significant reduction in total area invaded at 48 and 72 hours compared to WT, (48 hours: KO vs WT: 46 + 9%, p=0.0053; 72 hours: KO vs WT 53 + 10%, p=0.0130; one-way ANOVA with Tukey’s multiple-comparisons test). While Capns1 RES trended towards increased invasiveness compared to Capns1 KO, there were no statistically significant differences in total area invaded at 48 or 72 hours (p=0.1159 and p=0.3606, respectively). Furthermore, there were no significant differences in total area invaded at 48 or 72 hours between WT and Capns1 RES (p=0.1008 and p=0.0998, respectively).
In our resect-and-wait model orthotopic engraftment model, no significant differences in tumour growth rates were observed across the three AC2M2 genotypes (one-way ANOVA, p=0.6362) (Figure 1D). Tumours were resected by recovery surgery at 500mm3, rather than at a specific timepoint post-engraftment to ensure there were no significant differences in tumour volumes between genotypes at the time of resection (one-way ANOVA, p=0.2033). As illustrated in Figure 1E, Capns1 KO was associated with a 68 + 12% reduction in metastatic burden compared to WT, which was statistically significant (p<0.0001, one-way ANOVA with Tukey’s multiple-comparisons test). Capns1 RES was able to restore metastatic burden to 50 + 14% that of WT, but this was significantly less than WT (WT vs. Capns1 RES, p=0.0017), suggesting complete rescue was not achieved (Capns1 KO vs. Capns1 RES, p=0.4961). Representative whole-mount images of lungs are shown in Figure 1F, where each hyperintense green nodule represents a metastatic lesion.
In summary, Capns1 KO significantly impaired AC2M2 invasion in vitro, and lung metastasis in vivo. Despite restoring calpain-1 and calpain-2 proteolytic activity (Figure 1B), Capns1 rescue did not completely restore the WT phenotypes in either experiment. One possible explanation for this observed failure is off-target CRISPR-Cas9 activity, which could be mitigated by testing multiple guide RNAs or utilizing alternative methods of genetic disruption including shRNA knockdown. It is also worth noting that the Capns1 rescue construct lacked 129 nucleotides encoding 43 amino acids comprising most of the N-terminal glycine rich region of CAPNS1. Functional roles for the glycine rich domain of CAPNS1 remain to be fully elucidated, but there is evidence to suggest it plays a role in subcellular localization. The N-terminal glycine rich region of CAPNS1 has been proposed to play a role in phosphatidylinositol (PI) initiated autolysis and subsequent activation of calpain-1 at the plasma membrane (Imajoh et al., 1986). Additionally, anchoring of calpain-2 at the plasma membrane via phosphatidylinositol 4,5-bisphosphate (PIP2) binding has been reported to promote its activation (Leloup et al., 2010). Therefore, the physiological behaviour of our rescued calpain protein in vivo may not be reflected by in vitro zymography analysis, where excess CaCl2 in cell lysates artificially enhances proteolytic activity. Nevertheless, our findings are consistent with previous reports demonstrating the antimetastatic effects of genetic calpain-1/2 disruption (Grieve et al., 2016; Harper et al., 2025; Jeon et al., 2025; MacLeod et al., 2018), providing rationale for the development of selective calpain-1/2 inhibitors.
","references":[{"reference":"Arthur JS, Elce JS, Hegadorn C, Williams K, Greer PA. 2000. Disruption of the murine calpain small subunit gene, Capn4: calpain is essential for embryonic development but not for cell growth and division. Mol Cell Biol 20(12): 4474-81.
","pubmedId":"10825211","doi":""},{"reference":"Colucci F, Soudais C, Rosmaraki E, Vanes L, Tybulewicz VL, Di Santo JP. 1999. Dissecting NK cell development using a novel alymphoid mouse model: investigating the role of the c-abl proto-oncogene in murine NK cell differentiation. J Immunol 162(5): 2761-5.
","pubmedId":"10072522","doi":""},{"reference":"Elliott BE, Meens JA, SenGupta SK, Louvard D, Arpin M. 2005. The membrane cytoskeletal crosslinker ezrin is required for metastasis of breast carcinoma cells. Breast Cancer Res 7(3): R365-73.
","pubmedId":"15987432","doi":""},{"reference":"Ellison LF, Saint-Jacques N. 2023. Five-year cancer survival by stage at diagnosis in Canada. Health Rep 34(1): 3-15.
","pubmedId":"36716075","doi":""},{"reference":"Grieve S, Gao Y, Hall C, Hu J, Greer PA. 2016. Calpain Genetic Disruption and HSP90 Inhibition Combine To Attenuate Mammary Tumorigenesis. Mol Cell Biol 36(15): 2078-88.
","pubmedId":"27215381","doi":""},{"reference":"Harper D, Min JY, MacLeod JA, Cockburn S, Predko I, Gao Y, Greer PA, Shapovalov I. 2025. Calpain-1 and Calpain-2 Promote Breast Cancer Metastasis. Cells 14(17): 10.3390/cells14171314.
","pubmedId":"40940726","doi":""},{"reference":"Hoskin V, Ghaffari A, Laight BJ, SenGupta S, Madarnas Y, Nicol CJB, et al., Greer PA. 2022. Targeting the Ezrin Adaptor Protein Sensitizes Metastatic Breast Cancer Cells to Chemotherapy and Reduces Neoadjuvant Therapy-induced Metastasis. Cancer Res Commun 2(6): 456-470.
","pubmedId":"36923551","doi":""},{"reference":"Imajoh S, Kawasaki H, Suzuki K. 1986. The amino-terminal hydrophobic region of the small subunit of calcium-activated neutral protease (CANP) is essential for its activation by phosphatidylinositol. J Biochem 99(4): 1281-4.
","pubmedId":"3011770","doi":""},{"reference":"Jeon KH, Park S, Pak ES, Kim JA, Liu Y, Hwang SY, Na Y, Kwon Y. 2025. Calpain 2 Isoform-Specific Cleavage of Filamin A Enhances HIF1α Nuclear Translocation, Promoting Metastasis in Triple-Negative Breast Cancer. MedComm (2020) 6(4): e70147.
","pubmedId":"40151834","doi":""},{"reference":"Leloup L, Shao H, Bae YH, Deasy B, Stolz D, Roy P, Wells A. 2010. m-Calpain activation is regulated by its membrane localization and by its binding to phosphatidylinositol 4,5-bisphosphate. J Biol Chem 285(43): 33549-33566.
","pubmedId":"20729206","doi":""},{"reference":"MacLeod JA, Gao Y, Hall C, Muller WJ, Gujral TS, Greer PA. 2018. Genetic disruption of calpain-1 and calpain-2 attenuates tumorigenesis in mouse models of HER2+ breast cancer and sensitizes cancer cells to doxorubicin and lapatinib. Oncotarget 9(70): 33382-33395.
","pubmedId":"30279968","doi":""},{"reference":"Ono Y, Saido TC, Sorimachi H. 2016. Calpain research for drug discovery: challenges and potential. Nat Rev Drug Discov 15(12): 854-876.
","pubmedId":"27833121","doi":""},{"reference":"Ono Y, Sorimachi H. 2012. Calpains: an elaborate proteolytic system. Biochim Biophys Acta 1824(1): 224-36.
","pubmedId":"21864727","doi":""},{"reference":"Sanjana NE, Shalem O, Zhang F. 2014. Improved vectors and genome-wide libraries for CRISPR screening. Nat Methods 11(8): 783-784.
","pubmedId":"25075903","doi":""},{"reference":"Schindelin J, Arganda-Carreras I, Frise E, Kaynig V, Longair M, Pietzsch T, et al., Cardona A. 2012. Fiji: an open-source platform for biological-image analysis. Nat Methods 9(7): 676-82.
","pubmedId":"22743772","doi":""},{"reference":"Shapovalov I, Harper D, Greer PA. 2022. Calpain as a therapeutic target in cancer. Expert Opin Ther Targets 26(3): 217-231.
","pubmedId":"35225722","doi":""},{"reference":"Storr SJ, Carragher NO, Frame MC, Parr T, Martin SG. 2011. The calpain system and cancer. Nat Rev Cancer 11(5): 364-74.
","pubmedId":"21508973","doi":""},{"reference":"Surveillance Research Program, N. C. I. (2025). SEER*Explorer: An interactive website for SEER cancer statistics. https://seer.cancer.gov/statistics-network/explorer/
","pubmedId":"","doi":""},{"reference":"Wheelock MJ. 1982. Evidence for two structurally different forms of skeletal muscle Ca2+-activated protease. J Biol Chem 257(21): 12471-4.
","pubmedId":"6290467","doi":""}],"title":"Genetic disruption of Capns1 impairs metastatic phenotypes in murine mammary carcinoma cells
","reviews":[{"reviewer":{"displayName":"Franco Vizeacoumar"},"openAcknowledgement":true,"status":{"submitted":true}}],"curatorReviews":[]},{"id":"e613160b-12f6-42a9-9aed-b76ea792048a","decision":"accept","abstract":"Calpains are a family of 15 calcium-activated cysteine proteases that have emerged as potential antimetastatic targets in breast cancer. Calpain-1 and calpain-2 are ubiquitously expressed heterodimers composed of unique catalytic subunits (encoded by Capn1 and Capn2, respectively) and a common regulatory subunit (encoded by Capns1). Genetic disruption of Capns1 abolishes calpain-1 and calpain-2 activity. Using CRISPR-Cas9 mediated Capns1 knockout, we validated calpains-1/2 as promising therapeutic targets in a mouse model of mammary carcinoma. Capns1 knockout impaired cell invasion by 53 ± 10% in vitro and reduced lung metastasis by 68 ± 12% in an orthotopic engraftment mouse model.
","acknowledgements":"We would like to thank Chris Hall, Jeffrey Mewburn, Dr. Changnian Chi and Dr. Victoria Hoskin for technical assistance.
","authors":[{"affiliations":["Queen's University"],"departments":["Pathology and Molecular Medicine"],"credit":["conceptualization","dataCuration","formalAnalysis","methodology","visualization","writing_originalDraft"],"email":"danielle.harper@queensu.ca","firstName":"Danielle ","lastName":"Harper","submittingAuthor":true,"correspondingAuthor":true,"equalContribution":false,"WBId":null,"orcid":"0009-0009-1184-4923"},{"affiliations":["Queen's University"],"departments":["Pathology and Molecular Medicine"],"credit":["conceptualization","dataCuration","methodology","writing_reviewEditing"],"email":"ivan.shapovalov@queensu.ca","firstName":"Ivan ","lastName":"Shapovalov ","submittingAuthor":false,"correspondingAuthor":false,"equalContribution":false,"WBId":null,"orcid":null},{"affiliations":["Queen's University"],"departments":["Pathology and Molecular Medicine"],"credit":["dataCuration"],"email":"17sec6@queensu.ca","firstName":"Samantha ","lastName":"Cockburn","submittingAuthor":false,"correspondingAuthor":false,"equalContribution":false,"WBId":null,"orcid":null},{"affiliations":["Queen's University"],"departments":["Pathology and Molecular Medicine"],"credit":["dataCuration"],"email":"20ara4@queensu.ca","firstName":"Anya ","lastName":"Aaron","submittingAuthor":false,"correspondingAuthor":false,"equalContribution":false,"WBId":null,"orcid":null},{"affiliations":["Queen's University"],"departments":["Pathology and Molecular Medicine"],"credit":["dataCuration","methodology","resources"],"email":"yg2@queensu.ca","firstName":"Yan ","lastName":"Gao","submittingAuthor":false,"correspondingAuthor":false,"equalContribution":false,"WBId":null,"orcid":null},{"affiliations":["Queen's University"],"departments":["Pathology and Molecular Medicine",""],"credit":["conceptualization","fundingAcquisition","supervision","writing_reviewEditing"],"email":"greerp@queensu.ca","firstName":"Peter A","lastName":"Greer","submittingAuthor":false,"correspondingAuthor":false,"equalContribution":false,"WBId":null,"orcid":null}],"awards":[{"awardId":"PJT-166062","funderName":"Canada Institutes of Health Research (Canada)","awardRecipient":"Peter A Greer"}],"conflictsOfInterest":"The authors declare that there are no conflicts of interest present.
","dataTable":{"url":null},"extendedData":[],"funding":"This study was funded by a Canadian Institutes of Health Research project grant (PJT-166062) to P.A.G, and a Dean's Doctoral Award to DH.
","image":{"url":"https://portal.micropublication.org/uploads/e1222424e6b3b5039d5ea0f829a7d380.png"},"imageCaption":"A) Validation of genetic calpain-1/2 disruption in AC2M2 cells by immunoblotting (upper) and casein zymography (lower). (B) Relative distance invaded from 3D AC2M2 spheroids at 48 (left) and 72 hours (right). (C) Representative images of spheroids at 48 hours. (D) Resect-and-wait orthotopic engraftment metastasis model workflow (E) Tumour growth curves (F) Relative tumour growth rates in vivo. (G) Lung metastatic burden 10 days post tumour resection, normalised to WT control. (H) Representative whole mount images of lungs with GFP signal corresponding to metastatic lesions.
Capns1 knockout impairs AC2M2 invasion in vitro and metastatic progression in vivo
","methods":"Genetic manipulation of Capns1
CRISPR-Cas9 mediated knockout (KO) of mouse Capns1 in AC2M2 cells was achieved by transduction with lentivirus produced in HEK293T cells from psPAX2 and pMD.2G, and lentiCRISPRv2-Neo plasmids as previously described (Sanjana et al., 2014). The gene targeting guide RNA (m-Capns1 gRNA) sequence (5’-gtgctcggaggcctgatcag-3’) was cloned into the BsmBI restriction site of lentiCRISPRv2-Neo lentiviral shuttle vector (Primers, Forward: 5’-caccgtgctcggaggcctgatcag-3’, Reverse: 5’-aaacctgatcaggcctccgagcac -3’). Neomycin-selected transduced cells were diluted in 96 well plates to produce monoclonal populations of Capns1 KO AC2M2s. Using AC2M2 cDNA as a template, Capns1 was amplified by PCR and cloned into the PmeI restriction site of the pMSCV-puro retroviral vector (Primers, Forward: FW: 5’-cgacgtttaaactcatgttcttggtgaattcgttcttg-3’, Reverse: 5’- gtccgtttaaacactcagggtgcagcaaggtgtggcatgttgagc -3’). Rescue was achieved by transducing Capns1 KO AC2M2 cells with retrovirus produced in HEK23T cells transfected with pCL-Eco and pMSCV-Puro-Capns1. Calpain-1/2 protein expression and activity were assessed via immunoblotting and casein zymography, as previously described (Harper et al., 2025).
Spheroid Invasion
One x 104 GFP+ AC2M2 cells were seeded into each well of a round-bottom cell-repellent 96-well plate (Greiner Bio-One, Catalogue #: 650970). After 72 hours, spheroids were collected using a p1000 pipette with sterile cut tips and resuspended in 25% Matrigel (Corning; Catalogue #: 354230) in complete DMEM. Spheroids were plated on Ibidi chamber slides (Ibidi; Catalogue #: 80426) and incubated at 37oC for 30 minutes to allow the new layer of Matrigel to solidify. An initial image (time=0) of each spheroid was captured using an EVOS m7000 microscope on the GFP channel. Spheroids were subsequently imaged at 24, 48 and 72 hours. Quantification of invasion was performed in FIJI (Schindelin et al., 2012). The average distance invaded was estimated by calculating the mean of 4 measurements from the edge of each spheroid to the furthest point on the invasive front at 0o, 90o, 180o, and 270o positions. The total area invaded was calculated by subtracting the area of the spheroid (π x spheroid radius2) from the area contained within the borders of the invasive front [π x (spheroid radius + average distance invaded)2]. Within each biological replicate, data were normalized to the WT control. Statistical analyses were performed for each time point on biological replicate means using ordinary one-way ANOVA with Tukey’s multiple-comparisons test in Prism GraphPad 10.
Resect-and-wait spontaneous metastasis
Resect-and-wait experiments for spontaneous lung metastasis were performed as previously described (Harper et al., 2025; Hoskin et al., 2022). All experiments involving the use of animals were performed in accordance with the Canadian Council on Animal Care (CCAC) guidelines and with the approval of Queen’s University Animal Care Committee.
GFP+ AC2M2 cells were prepared in a 1:1 ratio of cell suspension (in PBS) to Matrigel. Using a 50µL Hamilton syringe (Hamilton; Catalogue #: 80500), 7500 AC2M2 cells were injected into the 4th mammary fat pad of 8-12 week old female BalbC-Rag2-/-/IL2Rgc-/- mice (Colucci et al., 1999). Tumour growth was monitored beginning on day 10 using circle-template-based estimates (Staedtler; Catalogue #: 977501) and tumours were resected by recovery surgery after reaching equivalent sizes (500mm3, ~18-22 days post engraftment). Mice were euthanised 10 days post-tumour resection and lungs were harvested for imaging on the GFP Ex/Em channel on the EVOS m7000 microscope (ThermoFisher Scientific, Catalogue #: AMF7000). Anterior and posterior images of the lungs were captured, and the metastatic burden was calculated by determining the % lung area occupied by GFP+ signal. For each experimental replicate, metastatic burden was normalised to WT control. Data was analysed using ordinary one-way ANOVA with Tukey’s multiple comparisons test in Prism GraphPad 10.
","reagents":"","patternDescription":"Triple-negative breast cancer (TNBC) is a heterogenous breast cancer subtype characterized by a lack of estrogen receptor (ER), progesterone receptor (PR), and human epidermal growth factor receptor 2 (HER2) expression. Across all breast cancer subtypes, progression from localized to metastatic disease is associated with 76.8% reduction in 5-year survival (Ellison & Saint-Jacques, 2023). The deadly consequences of metastatic progression are exacerbated for TNBC patients, with 5-year survival for stage IV disease at just 12.1% (Surveillance Research Program, 2025). This underscores an urgent need for therapies which can prevent or slow the metastatic progression of TNBC.
A growing number of preclinical and translational studies have implicated calpain proteases in cancer (Shapovalov et al., 2022; Storr et al., 2011). Human calpains are a family of 15 calcium-activated cysteine proteases (Ono & Sorimachi, 2012). The two most widely studied isoforms, calpain-1 and calpain-2 (referred to as calpain-1/2), are ubiquitously expressed heterodimers consisting of a unique large catalytic subunit, encoded by CAPN1 or CAPN2 genes respectively, and an obligate common regulatory subunit, encoded by CAPNS1 (Wheelock, 1982). Genetic disruption of CAPNS1 is associated with a loss of calpain-1 and calpain-2 activity (Arthur et al., 2000). At present, there are no clinically approved calpain inhibitors available. While several active-site directed calpain inhibitors have been developed, they produce off-target effects on other proteases and lack specificity for calpains, let alone individual calpain isoforms (Ono et al., 2016). We have employed genetic approaches to validate calpain-1/2 as promising therapeutic targets in TNBC.
We previously reported that genetic disruption of CAPNS1 impaired human MDA-MB-231 TNBC cell migration in vitro and attenuated lung metastasis in an orthotopic xenograft mouse model (Harper et al., 2025). Here, we demonstrate that CRISPR-Cas9 mediated knockout of Capns1 produces similar effects in an allogeneic mouse model using the AC2M2 murine mammary carcinoma cell line. AC2M2 is a highly metastatic variant of the TNBC-like SP1 mammary adenocarcinoma cell line derived in the laboratory of Dr. Bruce Elliott at Queen’s University (Elliott et al., 2005). Following validation of CRISPR-Cas9 mediated Capns1 knockout (KO) and gene add-back rescue (RES) by immunoblotting and casein zymography (Figure 1A), we employed a spheroid invasion assay to a observe how loss of calpain-1/2 activity affects 3D-invasion. Lung metastasis was evaluated in vivo using an orthotopic engraftment, resect-and-wait-mouse model.
To assess the impact of Capns1 KO on the ability of AC2M2 cells to invade the extracellular matrix, WT, Capns1 KO, and Capns1 RES AC2M2 spheroids were established in cell-repellent, round-bottom 96-well plates, and subsequently embedded into a 25% Matrigel matrix on an Ibidi chamber slide. As illustrated in Figure 1 panels B and C, Capns1 KO was associated with a statistically significant reduction in total area invaded at 48 and 72 hours compared to WT, (48 hours: KO vs WT: 46 + 9%, p=0.0053; 72 hours: KO vs WT 53 + 10%, p=0.0130; one-way ANOVA with Tukey’s multiple-comparisons test). While Capns1 RES trended towards increased invasiveness compared to Capns1 KO, there were no statistically significant differences in total area invaded at 48 or 72 hours (p=0.1159 and p=0.3606, respectively). Furthermore, there were no significant differences in total area invaded at 48 or 72 hours between WT and Capns1 RES (p=0.1008 and p=0.0998, respectively).
In our resect-and-wait model orthotopic engraftment model, tumours were resected by recovery surgery at 500mm3, rather than at a specific timepoint post-engraftment. This was ensure there were no significant differences in tumour volumes between genotypes at resection. If CAPNS1 knockout had an effect on tumour growth, we wanted to control for the possibility that a lower lung metastatic burden could be attributed to a smaller tumour size, rather than direct calpain mediated effects on metastatic dissemination. In our AC2M2 model, there were no significant differences in tumour growth rates, as demonstrated in figures 1E and 1F. The tumour growth curve illustrated in Figure 1E represents average tumour volumes between the day of first palpable tumour measurements (day 12) and the first resection surgery on day 21. Tumours were resected at various timepoints between day 21 and day 24. The tumour growth rate for each tumour was calculated using a non-linear regression between day 12 and the day of resection, and genotype averages were compared using a one-way ANOVA (p=0.6362).
As illustrated in Figure 1G, Capns1 KO was associated with a 68 + 12% reduction in metastatic burden compared to WT, which was statistically significant (p<0.0001, one-way ANOVA with Tukey’s multiple-comparisons test). Capns1 RES was able to restore metastatic burden to 50 + 14% that of WT, but this was significantly less than WT (WT vs. Capns1 RES, p=0.0017), suggesting complete rescue was not achieved (Capns1 KO vs. Capns1 RES, p=0.4961). Representative whole-mount images of lungs are shown in Figure 1F, where each hyperintense green nodule represents a metastatic lesion.
In summary, Capns1 KO significantly impaired AC2M2 invasion in vitro, and lung metastasis in vivo. Despite restoring calpain-1 and calpain-2 proteolytic activity (Figure 1B), Capns1 rescue did not completely restore the WT phenotypes in either experiment. One possible explanation for this observed failure is off-target CRISPR-Cas9 activity, which could be mitigated by testing multiple guide RNAs or utilising alternative methods of genetic disruption including shRNA knockdown. It is also worth noting that the Capns1 rescue construct lacked 129 nucleotides encoding 43 amino acids comprising most of the N-terminal glycine rich region of CAPNS1. Functional roles for the glycine rich domain of CAPNS1 remain to be fully elucidated, but there is evidence to suggest it plays a role in subcellular localization. The N-terminal glycine rich region of CAPNS1 has been proposed to play a role in phosphatidylinositol (PI) initiated autolysis and subsequent activation of calpain-1 at the plasma membrane (Imajoh et al., 1986). Additionally, anchoring of calpain-2 at the plasma membrane via phosphatidylinositol 4,5-bisphosphate (PIP2) binding has been reported to promote its activation (Leloup et al., 2010). Therefore, the physiological behaviour of our rescued calpain protein in vivo may not be reflected by in vitro zymography analysis, where excess CaCl2 in cell lysates artificially enhances proteolytic activity. Nevertheless, our findings are consistent with previous reports demonstrating the antimetastatic effects of genetic calpain-1/2 disruption (Grieve et al., 2016; Harper et al., 2025; Jeon et al., 2025; MacLeod et al., 2018), providing rationale for the development of selective calpain-1/2 inhibitors.
There are currently no calpain inhibitors approved for clinical use. While there are a number of inhibitors used in research applications, they lack specificity for individual calpain isoforms and inhibit other proteases, including the proteasome, cathepsins and caspases (Ono et al., 2016). Furthermore, systemic calpain inhibition may produce unwanted side effects. Germline loss of Capns1 or Capn2 is embryonic lethal but inducible or tissue specific Capns1 knockout appears to be well tolerated in adult mice (Arthur et al., 2000; Dutt et al., 2006; Takano et al., 2011; Kumar et al., 2014). Like many cytotoxic cancer therapies, calpain inhibitors would likely be contraindicated for pregnant women, especially during the first trimester. In mice, dogs, and humans, loss of function CAPN1 mutations result in a predisposition to cerebellar ataxia and muscle wasting (Wang et al. 2016). While calpain-3 is the major isoform expressed in muscle tissue, loss of Capns1 has also been shown to contribute to muscular dystrophy in aged mice (Piper et al., 2020). These considerations may be useful for informing hypothetical future decisions regarding the duration of calpain-inhibitor treatment as an anti-metastatic approach.
For short-term prevention of metastatic progression, for example between initial diagnosis and surgery, or during neoadjuvant immunotherapy, a calpain inhibitor may be well tolerated. However, if used as a long-term approach to limit further progression in the metastatic setting, the risk of adverse effects may increase. In summary, the ubiquitous nature of calpain expression raises concerns of off-target effects associated with calpain disruption, but current evidence from preclinical models suggests that calpain inhibitors are likely to be well tolerated, at least in the short term. However, in order to address these concerns, we require a selective calpain-1/2 inhibitor with pharmacokinetic properties that permit in vivo applications. Calpain proteases remain a promising anti-metastatic therapeutic target, and the development of selective calpain-1/2 inhibitors has the potential to improve clinical outcomes for TNBC patients.
","references":[{"reference":"Arthur JS, Elce JS, Hegadorn C, Williams K, Greer PA. 2000. Disruption of the murine calpain small subunit gene, Capn4: calpain is essential for embryonic development but not for cell growth and division. Mol Cell Biol 20(12): 4474-81.
","pubmedId":"10825211","doi":""},{"reference":"Colucci F, Soudais C, Rosmaraki E, Vanes L, Tybulewicz VL, Di Santo JP. 1999. Dissecting NK cell development using a novel alymphoid mouse model: investigating the role of the c-abl proto-oncogene in murine NK cell differentiation. J Immunol 162(5): 2761-5.
","pubmedId":"10072522","doi":""},{"reference":"Dutt P, Croall DE, Arthur JS, Veyra TD, Williams K, Elce JS, Greer PA. 2006. m-Calpain is required for preimplantation embryonic development in mice. BMC Dev Biol 6: 3.
","pubmedId":"16433929","doi":""},{"reference":"Elliott BE, Meens JA, SenGupta SK, Louvard D, Arpin M. 2005. The membrane cytoskeletal crosslinker ezrin is required for metastasis of breast carcinoma cells. Breast Cancer Res 7(3): R365-73.
","pubmedId":"15987432","doi":""},{"reference":"Ellison LF, Saint-Jacques N. 2023. Five-year cancer survival by stage at diagnosis in Canada. Health Rep 34(1): 3-15.
","pubmedId":"36716075","doi":""},{"reference":"Grieve S, Gao Y, Hall C, Hu J, Greer PA. 2016. Calpain Genetic Disruption and HSP90 Inhibition Combine To Attenuate Mammary Tumorigenesis. Mol Cell Biol 36(15): 2078-88.
","pubmedId":"27215381","doi":""},{"reference":"Harper D, Min JY, MacLeod JA, Cockburn S, Predko I, Gao Y, Greer PA, Shapovalov I. 2025. Calpain-1 and Calpain-2 Promote Breast Cancer Metastasis. Cells 14(17): 10.3390/cells14171314.
","pubmedId":"40940726","doi":""},{"reference":"Hoskin V, Ghaffari A, Laight BJ, SenGupta S, Madarnas Y, Nicol CJB, et al., Greer PA. 2022. Targeting the Ezrin Adaptor Protein Sensitizes Metastatic Breast Cancer Cells to Chemotherapy and Reduces Neoadjuvant Therapy-induced Metastasis. Cancer Res Commun 2(6): 456-470.
","pubmedId":"36923551","doi":""},{"reference":"Imajoh S, Kawasaki H, Suzuki K. 1986. The amino-terminal hydrophobic region of the small subunit of calcium-activated neutral protease (CANP) is essential for its activation by phosphatidylinositol. J Biochem 99(4): 1281-4.
","pubmedId":"3011770","doi":""},{"reference":"Jeon KH, Park S, Pak ES, Kim JA, Liu Y, Hwang SY, Na Y, Kwon Y. 2025. Calpain 2 Isoform-Specific Cleavage of Filamin A Enhances HIF1α Nuclear Translocation, Promoting Metastasis in Triple-Negative Breast Cancer. MedComm (2020) 6(4): e70147.
","pubmedId":"40151834","doi":""},{"reference":"Kumar V, Everingham S, Hall C, Greer PA, Craig AW. 2014. Calpains promote neutrophil recruitment and bacterial clearance in an acute bacterial peritonitis model. Eur J Immunol 44(3): 831-41.
","pubmedId":"24375267","doi":""},{"reference":"Leloup L, Shao H, Bae YH, Deasy B, Stolz D, Roy P, Wells A. 2010. m-Calpain activation is regulated by its membrane localization and by its binding to phosphatidylinositol 4,5-bisphosphate. J Biol Chem 285(43): 33549-33566.
","pubmedId":"20729206","doi":""},{"reference":"MacLeod JA, Gao Y, Hall C, Muller WJ, Gujral TS, Greer PA. 2018. Genetic disruption of calpain-1 and calpain-2 attenuates tumorigenesis in mouse models of HER2+ breast cancer and sensitizes cancer cells to doxorubicin and lapatinib. Oncotarget 9(70): 33382-33395.
","pubmedId":"30279968","doi":""},{"reference":"Ono Y, Saido TC, Sorimachi H. 2016. Calpain research for drug discovery: challenges and potential. Nat Rev Drug Discov 15(12): 854-876.
","pubmedId":"27833121","doi":""},{"reference":"Ono Y, Sorimachi H. 2012. Calpains: an elaborate proteolytic system. Biochim Biophys Acta 1824(1): 224-36.
","pubmedId":"21864727","doi":""},{"reference":"Piper AK, Sophocleous RA, Ross SE, Evesson FJ, Saleh O, Bournazos A, et al., Cooper ST. 2020. Loss of calpains-1 and -2 prevents repair of plasma membrane scrape injuries, but not small pores, and induces a severe muscular dystrophy. Am J Physiol Cell Physiol 318(6): C1226-C1237.
","pubmedId":"32348180","doi":""},{"reference":"Sanjana NE, Shalem O, Zhang F. 2014. Improved vectors and genome-wide libraries for CRISPR screening. Nat Methods 11(8): 783-784.
","pubmedId":"25075903","doi":""},{"reference":"Schindelin J, Arganda-Carreras I, Frise E, Kaynig V, Longair M, Pietzsch T, et al., Cardona A. 2012. Fiji: an open-source platform for biological-image analysis. Nat Methods 9(7): 676-82.
","pubmedId":"22743772","doi":""},{"reference":"Shapovalov I, Harper D, Greer PA. 2022. Calpain as a therapeutic target in cancer. Expert Opin Ther Targets 26(3): 217-231.
","pubmedId":"35225722","doi":""},{"reference":"Storr SJ, Carragher NO, Frame MC, Parr T, Martin SG. 2011. The calpain system and cancer. Nat Rev Cancer 11(5): 364-74.
","pubmedId":"21508973","doi":""},{"reference":"Surveillance Research Program, N. C. I. (2025). SEER*Explorer: An interactive website for SEER cancer statistics. https://seer.cancer.gov/statistics-network/explorer/
","pubmedId":"","doi":""},{"reference":"Takano J, Mihira N, Fujioka R, Hosoki E, Chishti AH, Saido TC. 2011. Vital role of the calpain-calpastatin system for placental-integrity-dependent embryonic survival. Mol Cell Biol 31(19): 4097-106.
","pubmedId":"21791606","doi":""},{"reference":"Wheelock MJ. 1982. Evidence for two structurally different forms of skeletal muscle Ca2+-activated protease. J Biol Chem 257(21): 12471-4.
","pubmedId":"6290467","doi":""},{"reference":"Wang Y, Hersheson J, Lopez D, Hammer M, Liu Y, Lee KH, et al., Baudry M. 2016. Defects in the CAPN1 Gene Result in Alterations in Cerebellar Development and Cerebellar Ataxia in Mice and Humans. Cell Rep 16(1): 79-91.
","pubmedId":"27320912","doi":""}],"title":"Genetic disruption of Capns1 impairs metastatic phenotypes in murine mammary carcinoma cells
","reviews":[],"curatorReviews":[]},{"id":"b5c22fcb-7f61-41f4-a5e3-58b60df0a841","decision":"publish","abstract":"Calpains are a family of 15 calcium-activated cysteine proteases that have emerged as potential antimetastatic targets in breast cancer. Calpain-1 and calpain-2 are ubiquitously expressed heterodimers composed of unique catalytic subunits (encoded by Capn1 and Capn2, respectively) and a common regulatory subunit (encoded by Capns1). Genetic disruption of Capns1 abolishes calpain-1 and calpain-2 activity. Using CRISPR-Cas9 mediated Capns1 knockout, we validated calpains-1/2 as promising therapeutic targets in a mouse model of mammary carcinoma. Capns1 knockout impaired cell invasion by 53 ± 10% in vitro and reduced lung metastasis by 68 ± 12% in an orthotopic engraftment mouse model.
","acknowledgements":"We would like to thank Chris Hall, Jeffrey Mewburn, Dr. Changnian Chi and Dr. Victoria Hoskin for technical assistance.
","authors":[{"affiliations":["Queen's University"],"departments":["Pathology and Molecular Medicine"],"credit":["conceptualization","dataCuration","formalAnalysis","methodology","visualization","writing_originalDraft"],"email":"danielle.harper@queensu.ca","firstName":"Danielle ","lastName":"Harper","submittingAuthor":true,"correspondingAuthor":true,"equalContribution":false,"WBId":null,"orcid":"0009-0009-1184-4923"},{"affiliations":["Queen's University"],"departments":["Pathology and Molecular Medicine"],"credit":["conceptualization","dataCuration","methodology","writing_reviewEditing"],"email":"ivan.shapovalov@queensu.ca","firstName":"Ivan ","lastName":"Shapovalov ","submittingAuthor":false,"correspondingAuthor":false,"equalContribution":false,"WBId":null,"orcid":null},{"affiliations":["Queen's University"],"departments":["Pathology and Molecular Medicine"],"credit":["dataCuration"],"email":"17sec6@queensu.ca","firstName":"Samantha ","lastName":"Cockburn","submittingAuthor":false,"correspondingAuthor":false,"equalContribution":false,"WBId":null,"orcid":null},{"affiliations":["Queen's University"],"departments":["Pathology and Molecular Medicine"],"credit":["dataCuration"],"email":"20ara4@queensu.ca","firstName":"Anya ","lastName":"Aaron","submittingAuthor":false,"correspondingAuthor":false,"equalContribution":false,"WBId":null,"orcid":null},{"affiliations":["Queen's University"],"departments":["Pathology and Molecular Medicine"],"credit":["dataCuration","methodology","resources"],"email":"yg2@queensu.ca","firstName":"Yan ","lastName":"Gao","submittingAuthor":false,"correspondingAuthor":false,"equalContribution":false,"WBId":null,"orcid":null},{"affiliations":["Queen's University"],"departments":["Pathology and Molecular Medicine",""],"credit":["conceptualization","fundingAcquisition","supervision","writing_reviewEditing"],"email":"greerp@queensu.ca","firstName":"Peter A","lastName":"Greer","submittingAuthor":false,"correspondingAuthor":false,"equalContribution":false,"WBId":null,"orcid":null}],"awards":[{"awardId":"PJT-166062","funderName":"Canada Institutes of Health Research (Canada)","awardRecipient":"Peter A Greer"}],"conflictsOfInterest":"The authors declare that there are no conflicts of interest present.
","dataTable":{"url":null},"extendedData":[],"funding":"This study was funded by a Canadian Institutes of Health Research project grant (PJT-166062) to P.A.G, and a Dean's Doctoral Award to DH.
","image":{"url":"https://portal.micropublication.org/uploads/e1222424e6b3b5039d5ea0f829a7d380.png"},"imageCaption":"A) Validation of genetic calpain-1/2 disruption in AC2M2 cells by immunoblotting (upper) and casein zymography (lower). (B) Relative distance invaded from 3D AC2M2 spheroids at 48 (left) and 72 hours (right). (C) Representative images of spheroids at 48 hours. (D) Resect-and-wait orthotopic engraftment metastasis model workflow (E) Tumour growth curves (F) Relative tumour growth rates in vivo. (G) Lung metastatic burden 10 days post tumour resection, normalised to WT control. (H) Representative whole mount images of lungs with GFP signal corresponding to metastatic lesions.
Capns1 knockout impairs AC2M2 invasion in vitro and metastatic progression in vivo
","methods":"Genetic manipulation of Capns1
CRISPR-Cas9 mediated knockout (KO) of mouse Capns1 in AC2M2 cells was achieved by transduction with lentivirus produced in HEK293T cells from psPAX2 and pMD.2G, and lentiCRISPRv2-Neo plasmids as previously described (Sanjana et al., 2014). The gene targeting guide RNA (m-Capns1 gRNA) sequence (5’-gtgctcggaggcctgatcag-3’) was cloned into the BsmBI restriction site of lentiCRISPRv2-Neo lentiviral shuttle vector (Primers, Forward: 5’-caccgtgctcggaggcctgatcag-3’, Reverse: 5’-aaacctgatcaggcctccgagcac -3’). Neomycin-selected transduced cells were diluted in 96 well plates to produce monoclonal populations of Capns1 KO AC2M2s. Using AC2M2 cDNA as a template, Capns1 was amplified by PCR and cloned into the PmeI restriction site of the pMSCV-puro retroviral vector (Primers, Forward: FW: 5’-cgacgtttaaactcatgttcttggtgaattcgttcttg-3’, Reverse: 5’- gtccgtttaaacactcagggtgcagcaaggtgtggcatgttgagc -3’). Rescue was achieved by transducing Capns1 KO AC2M2 cells with retrovirus produced in HEK23T cells transfected with pCL-Eco and pMSCV-Puro-Capns1. Calpain-1/2 protein expression and activity were assessed via immunoblotting and casein zymography, as previously described (Harper et al., 2025).
Spheroid Invasion
One x 104 GFP+ AC2M2 cells were seeded into each well of a round-bottom cell-repellent 96-well plate (Greiner Bio-One, Catalogue #: 650970). After 72 hours, spheroids were collected using a p1000 pipette with sterile cut tips and resuspended in 25% Matrigel (Corning; Catalogue #: 354230) in complete DMEM. Spheroids were plated on Ibidi chamber slides (Ibidi; Catalogue #: 80426) and incubated at 37oC for 30 minutes to allow the new layer of Matrigel to solidify. An initial image (time=0) of each spheroid was captured using an EVOS m7000 microscope on the GFP channel. Spheroids were subsequently imaged at 24, 48 and 72 hours. Quantification of invasion was performed in FIJI (Schindelin et al., 2012). The average distance invaded was estimated by calculating the mean of 4 measurements from the edge of each spheroid to the furthest point on the invasive front at 0o, 90o, 180o, and 270o positions. The total area invaded was calculated by subtracting the area of the spheroid (π x spheroid radius2) from the area contained within the borders of the invasive front [π x (spheroid radius + average distance invaded)2]. Within each biological replicate, data were normalized to the WT control. Statistical analyses were performed for each time point on biological replicate means using ordinary one-way ANOVA with Tukey’s multiple-comparisons test in Prism GraphPad 10.
Resect-and-wait spontaneous metastasis
Resect-and-wait experiments for spontaneous lung metastasis were performed as previously described (Harper et al., 2025; Hoskin et al., 2022). All experiments involving the use of animals were performed in accordance with the Canadian Council on Animal Care (CCAC) guidelines and with the approval of Queen’s University Animal Care Committee.
GFP+ AC2M2 cells were prepared in a 1:1 ratio of cell suspension (in PBS) to Matrigel. Using a 50µL Hamilton syringe (Hamilton; Catalogue #: 80500), 7500 AC2M2 cells were injected into the 4th mammary fat pad of 8-12 week old female BalbC-Rag2-/-/IL2Rgc-/- mice (Colucci et al., 1999). Tumour growth was monitored beginning on day 10 using circle-template-based estimates (Staedtler; Catalogue #: 977501) and tumours were resected by recovery surgery after reaching equivalent sizes (500mm3, ~18-22 days post engraftment). Mice were euthanised 10 days post-tumour resection and lungs were harvested for imaging on the GFP Ex/Em channel on the EVOS m7000 microscope (ThermoFisher Scientific, Catalogue #: AMF7000). Anterior and posterior images of the lungs were captured, and the metastatic burden was calculated by determining the % lung area occupied by GFP+ signal. For each experimental replicate, metastatic burden was normalised to WT control. Data was analysed using ordinary one-way ANOVA with Tukey’s multiple comparisons test in Prism GraphPad 10.
","reagents":"","patternDescription":"Triple-negative breast cancer (TNBC) is a heterogenous breast cancer subtype characterized by a lack of estrogen receptor (ER), progesterone receptor (PR), and human epidermal growth factor receptor 2 (HER2) expression. Across all breast cancer subtypes, progression from localized to metastatic disease is associated with 76.8% reduction in 5-year survival (Ellison & Saint-Jacques, 2023). The deadly consequences of metastatic progression are exacerbated for TNBC patients, with 5-year survival for stage IV disease at just 12.1% (Surveillance Research Program, 2025). This underscores an urgent need for therapies which can prevent or slow the metastatic progression of TNBC.
A growing number of preclinical and translational studies have implicated calpain proteases in cancer (Shapovalov et al., 2022; Storr et al., 2011). Human calpains are a family of 15 calcium-activated cysteine proteases (Ono & Sorimachi, 2012). The two most widely studied isoforms, calpain-1 and calpain-2 (referred to as calpain-1/2), are ubiquitously expressed heterodimers consisting of a unique large catalytic subunit, encoded by CAPN1 or CAPN2 genes respectively, and an obligate common regulatory subunit, encoded by CAPNS1 (Wheelock, 1982). Genetic disruption of CAPNS1 is associated with a loss of calpain-1 and calpain-2 activity (Arthur et al., 2000). At present, there are no clinically approved calpain inhibitors available. While several active-site directed calpain inhibitors have been developed, they produce off-target effects on other proteases and lack specificity for calpains, let alone individual calpain isoforms (Ono et al., 2016). We have employed genetic approaches to validate calpain-1/2 as promising therapeutic targets in TNBC.
We previously reported that genetic disruption of CAPNS1 impaired human MDA-MB-231 TNBC cell migration in vitro and attenuated lung metastasis in an orthotopic xenograft mouse model (Harper et al., 2025). Here, we demonstrate that CRISPR-Cas9 mediated knockout of Capns1 produces similar effects in an allogeneic mouse model using the AC2M2 murine mammary carcinoma cell line. AC2M2 is a highly metastatic variant of the TNBC-like SP1 mammary adenocarcinoma cell line derived in the laboratory of Dr. Bruce Elliott at Queen’s University (Elliott et al., 2005). Following validation of CRISPR-Cas9 mediated Capns1 knockout (KO) and gene add-back rescue (RES) by immunoblotting and casein zymography (Figure 1A), we employed a spheroid invasion assay to a observe how loss of calpain-1/2 activity affects 3D-invasion. Lung metastasis was evaluated in vivo using an orthotopic engraftment, resect-and-wait-mouse model.
To assess the impact of Capns1 KO on the ability of AC2M2 cells to invade the extracellular matrix, WT, Capns1 KO, and Capns1 RES AC2M2 spheroids were established in cell-repellent, round-bottom 96-well plates, and subsequently embedded into a 25% Matrigel matrix on an Ibidi chamber slide. As illustrated in Figure 1 panels B and C, Capns1 KO was associated with a statistically significant reduction in total area invaded at 48 and 72 hours compared to WT, (48 hours: KO vs WT: 46 + 9%, p=0.0053; 72 hours: KO vs WT 53 + 10%, p=0.0130; one-way ANOVA with Tukey’s multiple-comparisons test). While Capns1 RES trended towards increased invasiveness compared to Capns1 KO, there were no statistically significant differences in total area invaded at 48 or 72 hours (p=0.1159 and p=0.3606, respectively). Furthermore, there were no significant differences in total area invaded at 48 or 72 hours between WT and Capns1 RES (p=0.1008 and p=0.0998, respectively).
In our resect-and-wait model orthotopic engraftment model, tumours were resected by recovery surgery at 500mm3, rather than at a specific timepoint post-engraftment. This was ensure there were no significant differences in tumour volumes between genotypes at resection. If CAPNS1 knockout had an effect on tumour growth, we wanted to control for the possibility that a lower lung metastatic burden could be attributed to a smaller tumour size, rather than direct calpain mediated effects on metastatic dissemination. In our AC2M2 model, there were no significant differences in tumour growth rates, as demonstrated in figures 1E and 1F. The tumour growth curve illustrated in Figure 1E represents average tumour volumes between the day of first palpable tumour measurements (day 12) and the first resection surgery on day 21. Tumours were resected at various timepoints between day 21 and day 24. The tumour growth rate for each tumour was calculated using a non-linear regression between day 12 and the day of resection, and genotype averages were compared using a one-way ANOVA (p=0.6362).
As illustrated in Figure 1G, Capns1 KO was associated with a 68 + 12% reduction in metastatic burden compared to WT, which was statistically significant (p<0.0001, one-way ANOVA with Tukey’s multiple-comparisons test). Capns1 RES was able to restore metastatic burden to 50 + 14% that of WT, but this was significantly less than WT (WT vs. Capns1 RES, p=0.0017), suggesting complete rescue was not achieved (Capns1 KO vs. Capns1 RES, p=0.4961). Representative whole-mount images of lungs are shown in Figure 1F, where each hyperintense green nodule represents a metastatic lesion.
In summary, Capns1 KO significantly impaired AC2M2 invasion in vitro, and lung metastasis in vivo. Despite restoring calpain-1 and calpain-2 proteolytic activity (Figure 1B), Capns1 rescue did not completely restore the WT phenotypes in either experiment. One possible explanation for this observed failure is off-target CRISPR-Cas9 activity, which could be mitigated by testing multiple guide RNAs or utilising alternative methods of genetic disruption including shRNA knockdown. It is also worth noting that the Capns1 rescue construct lacked 129 nucleotides encoding 43 amino acids comprising most of the N-terminal glycine rich region of CAPNS1. Functional roles for the glycine rich domain of CAPNS1 remain to be fully elucidated, but there is evidence to suggest it plays a role in subcellular localization. The N-terminal glycine rich region of CAPNS1 has been proposed to play a role in phosphatidylinositol (PI) initiated autolysis and subsequent activation of calpain-1 at the plasma membrane (Imajoh et al., 1986). Additionally, anchoring of calpain-2 at the plasma membrane via phosphatidylinositol 4,5-bisphosphate (PIP2) binding has been reported to promote its activation (Leloup et al., 2010). Therefore, the physiological behaviour of our rescued calpain protein in vivo may not be reflected by in vitro zymography analysis, where excess CaCl2 in cell lysates artificially enhances proteolytic activity. Nevertheless, our findings are consistent with previous reports demonstrating the antimetastatic effects of genetic calpain-1/2 disruption (Grieve et al., 2016; Harper et al., 2025; Jeon et al., 2025; MacLeod et al., 2018), providing rationale for the development of selective calpain-1/2 inhibitors.
There are currently no calpain inhibitors approved for clinical use. While there are a number of inhibitors used in research applications, they lack specificity for individual calpain isoforms and inhibit other proteases, including the proteasome, cathepsins and caspases (Ono et al., 2016). Furthermore, systemic calpain inhibition may produce unwanted side effects. Germline loss of Capns1 or Capn2 is embryonic lethal but inducible or tissue specific Capns1 knockout appears to be well tolerated in adult mice (Arthur et al., 2000; Dutt et al., 2006; Takano et al., 2011; Kumar et al., 2014). Like many cytotoxic cancer therapies, calpain inhibitors would likely be contraindicated for pregnant women, especially during the first trimester. In mice, dogs, and humans, loss of function CAPN1 mutations result in a predisposition to cerebellar ataxia and muscle wasting (Wang et al. 2016). While calpain-3 is the major isoform expressed in muscle tissue, loss of Capns1 has also been shown to contribute to muscular dystrophy in aged mice (Piper et al., 2020). These considerations may be useful for informing hypothetical future decisions regarding the duration of calpain-inhibitor treatment as an anti-metastatic approach.
For short-term prevention of metastatic progression, for example between initial diagnosis and surgery, or during neoadjuvant immunotherapy, a calpain inhibitor may be well tolerated. However, if used as a long-term approach to limit further progression in the metastatic setting, the risk of adverse effects may increase. In summary, the ubiquitous nature of calpain expression raises concerns of off-target effects associated with calpain disruption, but current evidence from preclinical models suggests that calpain inhibitors are likely to be well tolerated, at least in the short term. However, in order to address these concerns, we require a selective calpain-1/2 inhibitor with pharmacokinetic properties that permit in vivo applications. Calpain proteases remain a promising anti-metastatic therapeutic target, and the development of selective calpain-1/2 inhibitors has the potential to improve clinical outcomes for TNBC patients.
","references":[{"reference":"Arthur JS, Elce JS, Hegadorn C, Williams K, Greer PA. 2000. Disruption of the murine calpain small subunit gene, Capn4: calpain is essential for embryonic development but not for cell growth and division. Mol Cell Biol 20(12): 4474-81.
","pubmedId":"10825211","doi":""},{"reference":"Colucci F, Soudais C, Rosmaraki E, Vanes L, Tybulewicz VL, Di Santo JP. 1999. Dissecting NK cell development using a novel alymphoid mouse model: investigating the role of the c-abl proto-oncogene in murine NK cell differentiation. J Immunol 162(5): 2761-5.
","pubmedId":"10072522","doi":""},{"reference":"Dutt P, Croall DE, Arthur JS, Veyra TD, Williams K, Elce JS, Greer PA. 2006. m-Calpain is required for preimplantation embryonic development in mice. BMC Dev Biol 6: 3.
","pubmedId":"16433929","doi":""},{"reference":"Elliott BE, Meens JA, SenGupta SK, Louvard D, Arpin M. 2005. The membrane cytoskeletal crosslinker ezrin is required for metastasis of breast carcinoma cells. Breast Cancer Res 7(3): R365-73.
","pubmedId":"15987432","doi":""},{"reference":"Ellison LF, Saint-Jacques N. 2023. Five-year cancer survival by stage at diagnosis in Canada. Health Rep 34(1): 3-15.
","pubmedId":"36716075","doi":""},{"reference":"Grieve S, Gao Y, Hall C, Hu J, Greer PA. 2016. Calpain Genetic Disruption and HSP90 Inhibition Combine To Attenuate Mammary Tumorigenesis. Mol Cell Biol 36(15): 2078-88.
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