TGFß engages MEK/ERK to differentially regulate benign and malignant pancreas cell function.

While TGFß signals are anti-proliferative in benign and well-differentiated pancreatic cells, TGFß appears to promote the progression of advanced cancers. To better understand dysregulation of the TGFß pathway, we first generated mouse models of neoplastic disease with TGFß receptor deficiencies. These models displayed reduced levels of pERK irrespective of KRAS mutation. Furthermore, exogenous TGFß led to rapid and sustained TGFBR1-dependent ERK phosphorylation in benign pancreatic duct cells. Similar to results that our group has published in colon cancer cells, inhibition of ERK phosphorylation in duct cells mitigated TGFß-induced upregulation of growth suppressive pSMAD2 and p21, prevented downregulation of the pro-growth signal CDK2 and ablated TGFß-induced EMT. These observations suggest that ERK is a key factor in growth suppressive TGFß signals, yet may also contribute to detrimental TGFß signaling such as EMT. In neoplastic PanIN cells, pERK was not necessary for either TGFß-induced pSMAD2 phosphorylation or CDK2 repression, but was required for upregulation of p21 and EMT indicating a partial divergence between TGFß and MEK/ERK in early carcinogenesis. In cancer cells, pERK had no effect on TGFß-induced upregulation of pSMAD2 and p21, suggesting the two pathways have completely diverged with respect to the cell cycle. Furthermore, inhibition of pERK both reduced levels of CDK2 and prevented EMT independent of exogenous TGFß, consistent with most observations identifying pERK as a tumor promoter. Combined, these data suggest that during carcinogenesis pERK initially facilitates and later antagonizes TGFß-mediated cell cycle arrest, yet remains critical for the pathological, EMT-inducing arm of TGFß signaling.

Collagen regulation of let-7 in pancreatic cancer involves TGF-ß1-mediated membrane type 1-matrix metalloproteinase expression.

Pancreatic ductal adenocarcinoma (PDAC) is associated with a pronounced collagen-rich fibrosis known as desmoplastic reaction; however, the role of fibrosis in PDAC is poorly understood. In this report we show that collagen can regulate the tumor suppressive let-7 family of microRNAs in pancreatic cancer cells. PDAC cells growing in 3D collagen gels repress mature let-7 without affecting the precursor form of let-7 in part through increased expression of membrane type 1-matrix metalloproteinase (MT1-MMP, MMP-14) and ERK1/2 activation. PDAC cells in collagen also demonstrate increased TGF-ß1 signaling, and blocking TGF-ß1 signaling attenuated collagen-induced MT1-MMP expression, ERK1/2 activation and repression of let-7 levels. Although MT1-MMP overexpression was not sufficient to inhibit let-7 on 2D tissue culture plastic, overexpression of MT1-MMP in PDAC cells embedded in 3D collagen gels or grown in vivo repressed let-7 levels. Importantly, MT1-MMP expression significantly correlated with decreased levels of let-7 in human PDAC tumor specimens. Overall, our study emphasizes the interplay between the key proteinase MT1-MMP and its substrate type I collagen in modulating microRNA expression, and identifies an additional mechanism by which fibrosis may contribute to PDAC progression.

Highly invasive transitional cell carcinoma of the bladder in a simian virus 40 T-antigen transgenic mouse model.

Transitional cell carcinoma (TCC), a neoplasm of urinary bladder urothelial cells, generally appears in either of two forms, papillary non-invasive or invasive TCC, although intermediate forms can occur. Each has a distinctive morphology and clinical course. Altered expression of the p53 and pRb genes has been associated with the more serious invasive TCC, suggesting that the loss of activity of these tumor suppressor proteins may have a causal role in this disease. To test this hypothesis directly, transgenic mice were developed that expressed the simian virus 40 large T antigen (TAg) in urothelial cells under the control of the cytokeratin 19 gene (CK19) regulatory elements. In one CK19-TAg lineage, all transgenic mice developed highly invasive bladder neoplasms that resembled invasive human bladder TCCs. Stages of disease progression included development of carcinoma in situ, stromal invasion, muscle invasion, rapid growth, and, in 20% of affected mice, intravascular lung metastasis. Papillary lesions never were observed. Western blot analysis indicated that TAg was bound to both p53 and pRb, which has been shown to cause inactivation of these proteins. Our findings support suggestions that (i) inactivation of p53 and/or pRb constitutes a causal step in the etiology of invasive TCC, (ii) papillary and invasive TCC may have different molecular causes, and (iii) carcinoma in situ can represent an early stage in the progression to invasive TCC.