Abstract
Cells in the pancreas that have undergone acinar-ductal metaplasia (ADM) can transform into premalignant cells that can eventually become cancerous. Although the epithelial-mesenchymal transition regulator Snail (Snai1) can cooperate with Kras in acinar cells to enhance ADM development, the contribution of Snail-related protein Slug (Snai2) to ADM development is not known. Thus, transgenic mice expressing Slug and Kras in acinar cells were generated. Surprisingly, Slug attenuated Kras-induced ADM development, ERK1/2 phosphorylation and proliferation. Co-expression of Slug with Kras also attenuated chronic pancreatitis-induced changes in ADM development and fibrosis. In addition, Slug attenuated TGF-α-induced acinar cell metaplasia to ductal structures and TGF-α-induced expression of ductal markers in ex vivo acinar explant cultures. Significantly, blocking the Rho-associated protein kinase ROCK1/2 in the ex vivo cultures induced expression of ductal markers and reversed the effects of Slug by inducing ductal structures. In addition, blocking ROCK1/2 activity in Slug-expressing Kras mice reversed the inhibitory effects of Slug on ADM, ERK1/2 phosphorylation, proliferation and fibrosis. Overall, these results increase our understanding of the role of Slug in ADM, an early event that can eventually lead to pancreatic cancer development.
Similar content being viewed by others
Introduction
Acinar-ductal metaplasia (ADM), a very early event in pancreatic ductal adenocarcinoma (PDAC) development, is a process by which cells lose their acinar characteristics to become duct-like in nature1,2,3. Since cells that have undergone ADM can transform into premalignant cells that can eventually become cancerous1,2,3, there is increasing interest in identifying factors that regulate these very early changes in the pancreatic tumorigenesis. There are a number of proteins expressed by acinar cells to maintain the acinar program. For example, PTF1A, important for differentiation of acinar cells from precursor cells during pancreas development, is required for maintenance of acinar cell differentiation in the adult pancreas2,4. In contrast, proteins that control the ductal state (e.g., Pdx1 and Sox9) promote the development of ADM1,2,3. Thus, a finely regulated balance between the acinar and ductal programs mediates ADM development.
Snail family of transcription factors, which play an important role in embryonic development, are well-known regulators of epithelial-mesenchymal transition, a process by which cells lose their epithelial characteristics to become mesenchymal5,6. We have shown that Snail (Snai1) induces invasion and scattering of pancreatic cancer cells in 3D collagen7. In contrast, Slug (Snai2)-expressing pancreatic cancer cells fail to scatter in 3D collagen8. However, inhibiting Rho-associated protein kinase ROCK1/2 reverses the effects of Slug and induces scattering of Slug-expressing pancreatic cancer cells in 3D collagen8. Since epithelial-mesenchymal transition can also be an early event during pancreatic cancer development9, we have also evaluated the effects of overexpressing Snail in acinar cells in vivo. We have shown that Snail overexpression in acinar cells cooperates with mutant Kras to promote ADM development10,11. Snail and Slug proteins can have similar and differing roles in development and cancer progression5,6; however, it is not known to what extent Slug mediates ADM development in the mouse pancreas.
In this report, we evaluate the role of Slug in ADM development by generating transgenic mice overexpressing human Slug in acinar cells. Slug expression in the mouse pancreas has no effect on tissue morphology. Since expression of mutant Kras in acinar cells induces ADM10,12,13, we evaluated the effects of co-expressing Slug and Kras in acinar cells. Surprisingly, Slug expression attenuates Kras-induced ADM development and proliferation. Co-expression of Slug with Kras also attenuates chronic pancreatitis-induced changes in ADM development and fibrosis. In addition, Slug attenuates TGF-α-induced acinar cell metaplasia to ductal structures and TGF-α-induced expression of ductal markers in ex vivo acinar explant cultures. Significantly, blocking ROCK1/2 activity in the ex vivo cultures induces expression of ductal markers and reverses the inhibitory effects of Slug by inducing ductal structures. Importantly, blocking ROCK1/2 activity in Slug-expressing Kras mice also reverses the inhibitory effects of Slug on ADM proliferation and fibrosis. Overall, these results increase our understanding of the role of Slug in ADM, an early event that can eventually lead to pancreatic cancer development.
Results
Slug expression in EL-KrasG12D mice attenuates acinar-ductal metaplasia (ADM)
Snail proteins have been shown to contribute to cancer progression5,6. We have previously published that expression of Snail (Snai1) in acinar cells of the pancreas enhances the effects of mutant Kras as demonstrated by increased ADM, increased expression of the ductal marker CK19 and increased proliferation10,11. While the role of Snail in pancreatic cancer progression is well established, the role of Slug (Snai2) in pancreatic tumorigenesis is less well understood. To evaluate the role of Slug in vivo, we generated TRE-Slug transgenic mice, where human Slug expression is driven by 7 tetracycline response elements (TRE) upstream of a minimal CMV promoter. The mice were crossed with EL-tTA mice to induce expression of Slug in acinar cells of the pancreas. While there was Slug mRNA and protein expression in the pancreas of EL-tTA/Slug (Slug) mice (Fig. 1a), H&E staining of Slug-expressing pancreatic tissue demonstrated no evidence of phenotypic changes (Fig. 1a). We next evaluated the effect of co-expressing Slug and Kras in the mouse pancreas. The Slug (EL-tTA/Tre-Slug) mice were crossed with EL-KrasG12D mice to generate mice that co-express Slug and Kras in acinar cells (Kras/Slug mice). As control, we assessed mice that expressed only mutant Kras in acinar cells (Kras mice). Note that there was no change in mouse Slug expression between the wild-type mice and the Kras mice, indicating that Kras does not affect endogenous Slug expression in vivo. Compared to control Kras mice, Kras/Slug mice demonstrated significant attenuation of ADM development in the Kras/Slug mice (Fig. 1b). There was also less condensed amylase expression in the Kras/Slug mice compared to control Kras mice (Fig. 1c), further indicating attenuation of ADM development in the Kras/Slug mice. There was also less staining of the ductal marker CK19 in the Kras/Slug mice compared to Kras mice (Fig. 1c). Since mutant Kras can increase p-ERK1/2 levels in the mouse pancreas (Fig. 1d)14, we also evaluated the effect of Slug on p-ERK1/2 levels. Compared to Kras mice, Kras/Slug mice demonstrated decreased p-ERK1/2 levels (Fig. 1d). We also evaluated the effects of Slug expression on Kras-driven proliferation using PCNA as a proliferation marker. The pancreas of Kras/Slug mice demonstrated significantly reduced proliferation compared to the pancreas of Kras mice (Fig. 1e). Overall, these results indicate that Slug attenuates the effects of mutant Kras in the mouse pancreas.
Slug expression in EL-KrasG12D mice attenuates chronic pancreatitis-induced changes in vivo
Since the effects of Slug in the pancreas of EL-KrasG12D mice were unexpected, we next evaluated the effects of Slug on ADM development following induction of pancreatitis in the EL-KrasG12D mice. Importantly, chronic pancreatitis has been shown to contribute to pancreatic cancer development and progression15,16. Chronic pancreatitis was induced by administering cerulein, a cholecystokinin analog that causes premature release of digestive enzymes and subsequent pancreatic damage10,11. Treatment of Kras mice with cerulein for 3 weeks resulted in more pronounced ADM changes, which were attenuated in the Kras/Slug mice (Fig. 2a). There was also less condensed amylase expression in the Kras/Slug mice compared to control Kras mice (Fig. 2a). Following cerulein treatment, there was also less CK19 staining (Fig. 2a) and significantly less PCNA staining (Fig. 2b) in the pancreas of Kras/Slug mice compared to the pancreas of Kras mice. Moreover, trichrome staining showed that there was also less pancreatic fibrosis in the cerulein-treated Kras/Slug mice compared to that present in the cerulein-treated Kras mice (Fig. 2c). These results indicate that Slug can attenuate the effects of Kras even following induction of chronic pancreatitis.
Slug attenuates TGF-α-mediated induced acinar cell metaplasia to ductal structures
To understand how Slug attenuates ADM development in the EL-KrasG12D mice, we cultured isolated mouse pancreatic acinar cells in 3D collagen. In this ex vivo explant model, acinar cells undergo ADM following treatment with growth factors that activate the EGFR17,18. Acinar cells were isolated from wild-type mice and grown in 3D collagen in the presence of TGF-α for 4–5 days. Phase microscopy of the 3D cultures showed that TGF-α treatment induced ‘duct-like’ structures in the isolated mouse acini (Fig. 3a, left), suggesting that acinar cells are undergoing ductal metaplasia. To further evaluate these ‘duct-like’ structures, the collagen gels were fixed, sectioned and stained. Compared to sections from untreated acinar cultures, sections from TGF-α-treated acinar cultures also showed these duct-like structures (Fig. 3a, middle). Quantification of these duct-like structures in the phase pictures showed that there was ~3-fold increase in the ADM events following TGF-α treatment (Fig. 3a, right).
We next evaluated the effects of Slug expression in these ex vivo explant cultures. Acinar cells were isolated from control wild-type littermates (EL-tTA+/Slug- = wild-type) and Slug-expressing mice (EL-tTA+/Slug+ = Slug), and treated with TGF-α for 5 days. Treatment of pancreatic acinar cells isolated from control littermates demonstrated a significant increase in the number of ADM events in 3D collagen (Fig. 3b). In contrast, acinar cells isolated from Slug mice showed minimal ADM events that were not affected by TGF-α treatment. These results indicate that Slug attenuates TGF-α-induced ADM development in ex vivo explant cultures. To understand how Slug blocks acinar cell metaplasia to ductal structures, we isolated mRNA from acinar cultures after 1 day, 3 days and 5 days of treatment with TGF-α and evaluated changes in Pdx1 and Sox9, which are regulators of the ductal program and promote acinar cell metaplasia to ductal structures19,20,21. In addition, we evaluated the effect on carbonic anhydrase II (CA II), which has been shown to be up regulated in pancreatic ductal lesions22. While there was not a difference in the relative Pdx1 expression between TGF-α-treated wild-type and Slug-expressing acinar cells (Fig. 3c), Slug-expressing acinar cells showed reduced relative induction of CA II and Sox9 compared to the relative induction of CA II and Sox9 in control wild-type acinar cells (Fig. 3c). We also evaluated whether there was activation of the acinar program in Slug-expressing mouse pancreas by evaluating expression of Ptf1a, the master regulator of acinar differentiation4. There was decreased Ptf1a expression in both control and Slug-expressing acinar cells at Day 3, with Ptf1a expression levels becoming undetectable on Day 5 of TGF-α treatment (Fig. 3c). Since Slug blocks ADM development in vivo and in ex vivo explant cultures, suppression of the ductal program rather than activation of the acinar program is likely how Slug blocks acinar cell metaplasia to ductal structures.
Inhibition of Rho-associated protein kinases (ROCK1/2) reverses the effects of Slug in ex vivo 3D acinar cultures
We have previously published that the differential effects of Snail and Slug proteins on 3D collagen invasion was through their effects on Rho signaling8. We have demonstrated that inhibition of ROCK1/2 activity reversed the effects of Slug expression and enhanced 3D collagen invasion8. Thus, we examined the contribution of Rac1 and Rho signaling to Slug attenuation of ADM in ex vivo explant cultures. Initially, we evaluated the effects of the ROCK1/2 inhibitor Y27632 and that of NSC23766, which inhibits the interaction between Rac1 and its guanine nucleotide exchange factor Tiam1, on acinar cell metaplasia to ductal structures in ex vivo explant cultures23,24. Acinar cells were isolated from wild-type mice, grown in 3D collagen, treated with TGF-α and co-treated with Y27632 or NSC23766. Y27632 significantly enhanced TGF-α-induced ADM events in the 3D collagen cultures. In contrast, NSC23766 attenuated TGF-α-induced ADM events (Fig. 4a). To understand how the ROCK1/2 inhibitor Y27632 enhances ADM events, we evaluated the effects of daily Y27632 treatment on TGF-α-mediated changes in the regulators of acinar and ductal state. Daily treatment with Y27632 enhanced Pdx1, CA II and Sox9 expression on Day 5. While TGF-α treatment decreased Ptf1a levels, daily treatment with Y27632 did not result in a significantly further decrease in Ptf1a levels on Day 3 (Fig. 4b). Together, these results indicate that the effects of effects of Y27632 are mediated partly through activation of the ductal program.
We next evaluated the extent to which ROCK1/2 inhibition can overcome the effects of Slug in the ex vivo 3D collagen cultures. Acinar cells were isolated from Slug mice and control wild-type littermates, grown in 3D collagen, and treated with Y27632. Y27632 increased ADM events in acinar cells isolated from not only the wild-type mice, but also from Slug mice (Fig. 4c). Similarly, Fasudil, another ROCK1/2 inhibitor25, increased ADM events in acinar cells isolated from Slug mice (Fig. 4c).
ROCK1/2 inhibition reverses the effects of Slug expression in KrasG12D mice
As Fasudil has been shown to effectively block ROCK1/2 activity in mouse models26, we evaluated whether Fasudil could reverse the effects of Slug in EL-KrasG12D mice. Kras/Slug mice were treated with Fasudil for 4 weeks and the pancreas were collected and analyzed for ADM events, fibrosis and proliferation. Initially, we evaluated the effects of Fasudil on p-MLC (S19). Treatment with Fasudil decreased p-MLC staining in pancreas collected from mice treated with Fasudil (Fig. 5a). Significantly, Fasudil treatment enhanced ADM events and fibrosis (Fig. 5b,d). There was also increased CK19, p-ERK1/2 and PCNA staining in pancreas from mice treated with Fasudil (Fig. 5c,d). Overall, consistent with our findings in the ex vivo explant cultures, ROCK1/2 inhibition also reverses the inhibitory effects of Slug on Kras-induced phenotypic changes in vivo.
Discussion
Pancreatic cancer is currently the 3rd leading cause of cancer related deaths in the US and it is projected to become the 2nd leading cause of cancer related deaths in the US by 202027,28. Although some progress has been made in the treatment of patients with PDAC through the use of multi-agent chemotherapy27,29, a better understanding of the factors regulating PDAC initiation may help to prevent PDAC development and/or identify potential therapeutic targets. ADM has been shown to be one of the very early changes in PDAC tumorigenesis1,2,3. There is compelling evidence from mouse studies demonstrating that ADM can progress to PanIN lesions, which can then further progress to PDAC tumors1,2,3. Importantly, ADM is frequently associated with PanIN lesions seen in human PDAC tumors30,31. In mouse studies, ADM development can be induced by expression of mutant Kras, by overexpression of TGF-α, or by induction of pancreatitis1,2,3. Significantly, in this report we show that Slug can attenuate both Kras-mediated and pancreatitis-induced ADM development in vivo and TGF-α-driven ADM development in ex vivo acinar explant cultures.
Snail family proteins have been shown to play an important role in pancreatic cancer development and progression5,6. We have previously shown that co-expression of Snail with mutant Kras in acinar cells potentiates the effects of Kras10,11. Snail enhances Kras-driven ADM development and associated fibro-inflammatory stromal reaction10,11. We have also shown that expression of Snail in pancreatic cancer cells promotes invasion in 3D collagen7,8. Significantly, Snail is induced early in tumorigenesis in the KPC mouse model prior to development of any obvious pancreatic tumors9. Even though ablation of Snail fails to prevent metastasis in the KPC mouse model, Snail mediates resistance to chemotherapy in the KPC mouse model32. While the role of Snail in pancreatic cancer development and progression has been demonstrated, the role of Slug in pancreatic cancer tumorigenesis is less well understood. In contrast to the effects of Snail on Kras-driven ADM development, we show that Slug attenuates Kras-driven ADM, indicating that Snail and Slug can have opposing effects during pancreatic cancer progression.
Importantly, Snail and Slug proteins were also shown to have differing roles during breast cancer development and progression33. Slug, but not Snail, is expressed in normal mammary epithelial cells enriched for mammary stem cells33. Conversely, Snail, but not Slug, is activated during breast cancer progression and is associated with the tumor-initiating phenotype in breast cancer cells33. Snail and Slug proteins are also found to differentially regulate pluripotency genes during reprogramming by having opposing effects on nanog promoter activity34. Consequently, overexpression of Snail and Slug proteins results in opposite effects on nanog-driven induction of pluripotent stem cells34. Moreover, Snail knockout mice die early in gestation while Slug-deficient mice are viable with minimal abnormalities35,36,37, indicating that Snail and Slug proteins also have differing roles during embryonic development.
Significantly, in this report we demonstrate that treatment of Kras/Slug mice with the ROCK1/2 inhibitor reverses the inhibitory effects of Slug on ADM development, proliferation and fibrosis. ROCK1/2 inhibitors also reverse the effects of Slug in ex vivo explant cultures and enhance ADM development. The effects of ROCK1/2 inhibitors are likely due to activation of the ductal program, as Y27632 enhances the ductal regulator Pdx1 and Sox9 and increases expression of the ductal marker CA II. Our findings are consistent with previous reports showing that Rac1 is required for mutant Kras- and pancreatitis-induced ADM development38,39. Note that Rac and Rho signaling exhibit an antagonistic relationship, and that a reciprocal balance between Rac and Rho activity determines cellular morphology and function40,41.
Overall, we show that Slug attenuates ADM development in ex vivo and in vivo models and that blocking ROCK1/2 activity can reverse the effects of Slug in these models. These results increase our understanding of the role of Slug in ADM, an early event that can eventually lead to pancreatic cancer development.
Methods
Antibodies/reagents
General tissue culture supplies were purchased from VWR (West Chester, PA). Antibodies against Slug (sc-15391), α-tubulin (sc-8035), amylase (SC46657) and proliferating cell nuclear antigen (PCNA; sc-56) were obtained from Santa Cruz. Antibodies against p-MLC2(S19) (3671) and p-ERK1/2(T202/Y204) (4370) were purchased from Cell Signaling, while the antibody against cytokeratin-19 (CK19; TROMA-III) was obtained from the University of Iowa. The Rac1 inhibitor NSC23766 (553508) and the ROCK1/2 inhibitor Y27632 (688001) were purchased from Calbiochem, while the ROCK1/2 inhibitor Fasudil (HA-1077) was obtained from Selleck Chemicals. Rat-tail type I collagen (354249) was purchased from Corning, collagenase I (LS004194) was from Worthington Biochemical, and cerulein (C9026) and soybean trypsin inhibitor (T6522) were obtained from Sigma.
Transgenic mice
All animal work and procedures were approved by the Northwestern University Institutional Animal Care and Use Committee (IACUC). In addition, all experiments were performed in accordance with relevant guidelines and regulations. TRE-Slug transgenic mice, in which Slug expression is under the control of seven tet-responsive elements (TRE) upstream of a minimal cytomegalovirus (CMV) promoter, were created by the Transgenic Core Facility at Northwestern University (Chicago, IL). The TRE-Slug mice were crossed with EL-tTA mice, kindly provided by Dr. Eric Sandgren (University of Wisconsin, Madison, WI)42, to generate EL-tTA/TRE-Slug bigenic (Slug) mice. In EL-tTa mice, the transactivator tTa is expressed downstream of elastase promoter, thus enabling targeting of Slug to pancreatic acinar cells. The bigenic mice were further crossed with EL-KrasG12D (Kras) mice12, which express constitutively active mutant Kras in the pancreatic acinar cells, to generate Kras/Slug mice. To evaluate the effect of chronic pancreatitis in Kras and Kras/Slug mice, two-month old mice were i.p. injected with cerulein (100 μg/kg) daily for 5 days per week for 3 weeks10,11. Pancreatic tissue samples were collected 17 days after cessation of cerulein treatment. Similarly, to evaluate the effects of ROCK1/2 inhibition in vivo, two-month Kras/Slug mice were i.p. injected with Fasudil (25 mg/kg) daily for 5 days per week for 4 weeks26.
Histochemistry
The extent of ADM, defined by vacuolization of the normal acini with formation of abnormal ducts along with evidence of fibrosis was assessed, and a score of less than 25% (1+), 25% to 75% (2+), or more than 75% (3+) of the pancreas containing ADM was assigned to each mouse10,13. The samples were trichrome stained to assess for pancreatic fibrosis10,13.
Immunohistochemistry/Immunofluorescence
Pancreatic tissue specimens from Kras and Kras/Slug mice were stained for amylase, CK19, PCNA, p-MLC2(S19) and p-ERK1/2(T202/Y204). Antigen retrieval was conducted as previously described10,13. Photographs for quantitative comparison were taken using FeinOptic microscope and Jenoptik ProgRes C5 camera. Number of Kras and Kras/Slug mice with no staining (0), less than 5% (1+), 5% to 25% (2+), or more than 25% (3+) of the pancreas with CK19 staining was determined. Relative number of p-ERK1/2(+) and PCNA(+) nuclei in Kras and Kras/Slug mice were quantified.
Western blotting
Immunoblotting for Slug and α-tubulin was done as previously described8.
Quantitative real time PCR
Reverse transcription of mRNA to cDNA was performed using TaqMan Reverse Transcription reagents from Applied Biosystems. Quantitative gene expression was performed with gene-specific TaqMan probes, TaqMan Universal PCR Master Mix, and the 7500 Fast Real-time PCR System from Applied Biosystems. The data were then quantified with the comparative CT method for relative gene expression.
Ex vivo 3D collagen cultures
The pancreas was removed, washed, minced into 1–2-mm pieces, and digested with solution containing collagenase I and soybean trypsin inhibitor at 37 °C for 30 min18,43. The collagen digestion was stopped by adding media containing 10% FBS. The digested pancreatic pieces were further washed and pipetted through 100-μm mesh to obtain pancreatic acinar cells. The freshly isolated pancreatic acinar cells were plated in Waymouth media solution containing neutralized collagen (2.2 mg/ml), and allowed to form 3D collagen gel over 15 min at 37 °C. The Waymouth media containing EGF (25 ng/mL) and FBS (2.5%) was then added on top of the gel. The media was replaced the next day and every other day with fresh Waymouth media containing EGF (25 ng/mL) and FBS (2.5%) that was supplemented with TGF-α (50 ng/ml). In additional experiments, the ROCK1/2 inhibitors Y276322 (10 μM) and Fasudil (25 μM), or the Rac1 inhibitor NSC23766 (20 μM) were added to the ex vivo cultures. After 4–5 days, the number of ‘duct-like’ structures developing in the acinar cells was counted using a Zeiss Axiovert 40 CFL microscope and pictures were taken with a Nikon Coolpix 4500 camera. The collagen gels were then fixed in formaldehyde, embedded in paraffin, and gel-sections stained to identify the ductal structures44. The collagen gels were also processed for gene expression analysis by qRT-PCR.
Statistical analysis
In vivo and in vitro results were compared using t test analysis. Error bars represent standard error of the mean. All analyses were performed on GraphPad Prism 6 developed for Mac OS X.
Additional Information
How to cite this article: Ebine, K. et al. Slug inhibits pancreatic cancer initiation by blocking Kras-induced acinar-ductal metaplasia. Sci. Rep. 6, 29133; doi: 10.1038/srep29133 (2016).
References
Reichert, M. & Rustgi, A. K. Pancreatic ductal cells in development, regeneration, and neoplasia. J Clin Invest 121, 4572–4578, doi: 10.1172/JCI57131 (2011).
Murtaugh, L. C. & Keefe, M. D. Regeneration and repair of the exocrine pancreas. Annu Rev Physiol 77, 229–249, doi: 10.1146/annurev-physiol-021014-071727 (2015).
Bailey, J. M., DelGiorno, K. E. & Crawford, H. C. The secret origins and surprising fates of pancreas tumors. Carcinogenesis 35, 1436–1440, doi: 10.1093/carcin/bgu056 (2014).
Krah, N. M. et al. The acinar differentiation determinant PTF1A inhibits initiation of pancreatic ductal adenocarcinoma. Elife 4, doi: 10.7554/eLife.07125 (2015).
Krantz, S. B., Shields, M. A., Dangi-Garimella, S., Munshi, H. G. & Bentrem, D. J. Contribution of epithelial-to-mesenchymal transition and cancer stem cells to pancreatic cancer progression. J Surg Res 173, 105–112, doi: S0022-4804(11)00749-9 (2012).
Thiery, J. P., Acloque, H., Huang, R. Y. & Nieto, M. A. Epithelial-mesenchymal transitions in development and disease. Cell 139, 871–890, doi: S0092-8674(09)01419-6 (2009).
Shields, M. A., Dangi-Garimella, S., Krantz, S. B., Bentrem, D. J. & Munshi, H. G. Pancreatic Cancer Cells Respond to Type I Collagen by Inducing Snail Expression to Promote Membrane Type 1 Matrix Metalloproteinase-dependent Collagen Invasion. J Biol Chem 286, 10495–10504, doi: M110.195628 (2011).
Shields, M. A., Krantz, S. B., Bentrem, D. J., Dangi-Garimella, S. & Munshi, H. G. Interplay between beta1-integrin and Rho signaling regulates differential scattering and motility of pancreatic cancer cells by Snail and Slug proteins. J Biol Chem 287, 6218–6229, doi: M111.308940 (2012).
Rhim, A. D. et al. EMT and dissemination precede pancreatic tumor formation. Cell 148, 349–361, doi: S0092-8674(11)01369-9 (2012).
Shields, M. A. et al. Snail Cooperates with KrasG12D to Promote Pancreatic Fibrosis. Mol Cancer Res 11, 1078–1087, doi: 1541-7786.MCR-12-0637 (2013).
Knab, L. M. et al. Snail Cooperates with KrasG12D In Vivo to Increase Stem Cell Factor and Enhance Mast Cell Infiltration. Mol Cancer Res 12, 1440–1448, doi: 10.1158/1541-7786.MCR-14-0111 (2014).
Grippo, P. J., Nowlin, P. S., Demeure, M. J., Longnecker, D. S. & Sandgren, E. P. Preinvasive pancreatic neoplasia of ductal phenotype induced by acinar cell targeting of mutant Kras in transgenic mice. Cancer Res 63, 2016–2019 (2003).
Krantz, S. B. et al. MT1-MMP cooperates with Kras(G12D) to promote pancreatic fibrosis through increased TGF-beta signaling. Mol Cancer Res 9, 1294–1304, doi: 1541-7786.MCR-11-0023 (2011).
Collins, M. A. et al. Oncogenic Kras is required for both the initiation and maintenance of pancreatic cancer in mice. J Clin Invest 122, 639–653, doi: 10.1172/JCI59227 (2012).
Yadav, D. & Lowenfels, A. B. The epidemiology of pancreatitis and pancreatic cancer. Gastroenterology 144, 1252–1261, doi: S0016-5085(13)00168-6 (2013).
Perez-Mancera, P. A., Guerra, C., Barbacid, M. & Tuveson, D. A. What we have learned about pancreatic cancer from mouse models. Gastroenterology 142, 1079–1092, doi: S0016-5085(12)00315-0 (2012).
Crawford, H. C., Scoggins, C. R., Washington, M. K., Matrisian, L. M. & Leach, S. D. Matrix metalloproteinase-7 is expressed by pancreatic cancer precursors and regulates acinar-to-ductal metaplasia in exocrine pancreas. J Clin Invest 109, 1437–1444, doi: 10.1172/JCI15051 (2002).
Liou, G. Y. et al. Macrophage-secreted cytokines drive pancreatic acinar-to-ductal metaplasia through NF-kappaB and MMPs. J Cell Biol 202, 563–577, doi: jcb.201301001 (2013).
Fukuda, A. & Chiba, T. Sox9-dependent acinar-to-ductal reprogramming is critical for pancreatic intraepithelial neoplasia formation. Gastroenterology 145, 904–907, doi: 10.1053/j.gastro.2013.08.028 (2013).
Miyatsuka, T. et al. Persistent expression of PDX-1 in the pancreas causes acinar-to-ductal metaplasia through Stat3 activation. Genes Dev 20, 1435–1440, doi: 10.1101/gad.1412806 (2006).
Kopp, J. L. et al. Identification of Sox9-dependent acinar-to-ductal reprogramming as the principal mechanism for initiation of pancreatic ductal adenocarcinoma. Cancer Cell 22, 737–750, doi: 10.1016/j.ccr.2012.10.025 (2012).
Inada, A., Nienaber, C., Fonseca, S. & Bonner-Weir, S. Timing and expression pattern of carbonic anhydrase II in pancreas. Dev Dyn 235, 1571–1577, doi: 10.1002/dvdy.20754 (2006).
Gao, Y., Dickerson, J. B., Guo, F., Zheng, J. & Zheng, Y. Rational design and characterization of a Rac GTPase-specific small molecule inhibitor. Proceedings of the National Academy of Sciences of the United States of America 101, 7618–7623, doi: 10.1073/pnas.0307512101 (2004).
Ishizaki, T. et al. Pharmacological Properties of Y-27632, a Specific Inhibitor of Rho-Associated Kinases. Molecular Pharmacology 57, 976–983 (2000).
Nagumo, H. et al. Rho kinase inhibitor HA-1077 prevents Rho-mediated myosin phosphatase inhibition in smooth muscle cells. Am J Physiol Cell Physiol 278, C57–65 (2000).
Zhou, Y. et al. Inhibition of mechanosensitive signaling in myofibroblasts ameliorates experimental pulmonary fibrosis. J Clin Invest 123, 1096–1108, doi: 10.1172/JCI66700 (2013).
Ryan, D. P., Hong, T. S. & Bardeesy, N. Pancreatic adenocarcinoma. N Engl J Med 371, 1039–1049, doi: 10.1056/NEJMra1404198 (2014).
Siegel, R. L., Miller, K. D. & Jemal, A. Cancer statistics, 2016. CA Cancer J Clin 66, 7–30, doi: 10.3322/caac.21332 (2016).
Garrido-Laguna, I. & Hidalgo, M. Pancreatic cancer: from state-of-the-art treatments to promising novel therapies. Nat Rev Clin Oncol 12, 319–334, doi: 10.1038/nrclinonc.2015.53 (2015).
Brune, K. et al. Multifocal neoplastic precursor lesions associated with lobular atrophy of the pancreas in patients having a strong family history of pancreatic cancer. Am J Surg Pathol 30, 1067–1076, doi: pas.0000213265.84725.0b (2006).
Zhu, L., Shi, G., Schmidt, C. M., Hruban, R. H. & Konieczny, S. F. Acinar cells contribute to the molecular heterogeneity of pancreatic intraepithelial neoplasia. Am J Pathol 171, 263–273, doi: 10.2353/ajpath.2007.061176 (2007).
Zheng, X. et al. Epithelial-to-mesenchymal transition is dispensable for metastasis but induces chemoresistance in pancreatic cancer. Nature 527, 525–530, doi: 10.1038/nature16064 (2015).
Ye, X. et al. Distinct EMT programs control normal mammary stem cells and tumour-initiating cells. Nature 525, 256–260, doi: 10.1038/nature14897 (2015).
Gingold, J. A. et al. A genome-wide RNAi screen identifies opposing functions of Snai1 and Snai2 on the Nanog dependency in reprogramming. Mol Cell 56, 140–152, doi: 10.1016/j.molcel.2014.08.014 (2014).
Jiang, R., Lan, Y., Norton, C. R., Sundberg, J. P. & Gridley, T. The Slug gene is not essential for mesoderm or neural crest development in mice. Dev Biol 198, 277–285, doi: S0012160698989096 (1998).
Nieto, M. A., Sargent, M. G., Wilkinson, D. G. & Cooke, J. Control of cell behavior during vertebrate development by Slug, a zinc finger gene. Science 264, 835–839 (1994).
Carver, E. A., Jiang, R., Lan, Y., Oram, K. F. & Gridley, T. The mouse snail gene encodes a key regulator of the epithelial-mesenchymal transition. Mol Cell Biol 21, 8184–8188, doi: 10.1128/MCB.21.23.8184-8188.2001 (2001).
Wu, C. Y. et al. PI3K regulation of RAC1 is required for KRAS-induced pancreatic tumorigenesis in mice. Gastroenterology 147, 1405-1416 e1407, doi: 10.1053/j.gastro.2014.08.032 (2014).
Heid, I. et al. Early requirement of rac1 in a mouse model of pancreatic cancer. Gastroenterology 141, 719-730 e717, doi: S0016-5085(11)00598-1 (2011).
Sander, E. E., ten Klooster, J. P., van Delft, S., van der Kammen, R. A. & Collard, J. G. Rac downregulates Rho activity: reciprocal balance between both GTPases determines cellular morphology and migratory behavior. J Cell Biol 147, 1009–1022 (1999).
Sanz-Moreno, V. et al. Rac activation and inactivation control plasticity of tumor cell movement. Cell 135, 510–523, doi: S0092-8674(08)01236-1 (2008).
Guerra, C. et al. Chronic pancreatitis is essential for induction of pancreatic ductal adenocarcinoma by K-Ras oncogenes in adult mice. Cancer Cell 11, 291–302 (2007).
Gout, J. et al. Isolation and culture of mouse primary pancreatic acinar cells. J Vis Exp, doi: 10.3791/50514 (2013).
Chow, C. R. et al. Cancer Cell Invasion in Three-dimensional Collagen Is Regulated Differentially by Galpha13 Protein and Discoidin Domain Receptor 1-Par3 Protein Signaling. J Biol Chem 291, 1605–1618, doi: 10.1074/jbc.M115.669606 (2016).
Acknowledgements
This work was supported by grants R01CA126888 and R01CA186885 (to H.G. Munshi) from the NCI and a Merit award I01BX001363 (to H.G. Munshi) from the Department of Veterans Affairs. This research was also supported by the training grant T32CA070085 (to C.R. Chow) from the NCI.
Author information
Authors and Affiliations
Contributions
K.E., C.R.C., B.T.D., H.Z.H. and K.K. performed the experiments, analyzed the data, and edited the manuscript. P.J.G. provided reagents. H.G.M. designed the studies, analyzed the data, wrote and edited the manuscript.
Corresponding author
Ethics declarations
Competing interests
The authors declare no competing financial interests.
Rights and permissions
This work is licensed under a Creative Commons Attribution 4.0 International License. The images or other third party material in this article are included in the article’s Creative Commons license, unless indicated otherwise in the credit line; if the material is not included under the Creative Commons license, users will need to obtain permission from the license holder to reproduce the material. To view a copy of this license, visit http://creativecommons.org/licenses/by/4.0/
About this article
Cite this article
Ebine, K., Chow, C., DeCant, B. et al. Slug inhibits pancreatic cancer initiation by blocking Kras-induced acinar-ductal metaplasia. Sci Rep 6, 29133 (2016). https://doi.org/10.1038/srep29133
Received:
Accepted:
Published:
DOI: https://doi.org/10.1038/srep29133
- Springer Nature Limited