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(American Journal of Pathology. 1999;154:1693-1700.)
© 1999 American Society for Investigative Pathology

Regular Articles

Acceleration of c-myc-Induced Hepatocarcinogenesis by Co-Expression of Transforming Growth Factor (TGF)- in Transgenic Mice Is Associated with TGF-ß1 Signaling Disruption

Eric Santoni-Rugiu^*, Michael R. Jensen^*, Valentina M. Factor^* and Snorri S. Thorgeirsson^*

From the Laboratory of Experimental Carcinogenesis,^*
Division of Basic Sciences, National Cancer Institute, Bethesda, Maryland, and the Department of Experimental Pathology,
University of Pisa, Pisa, Italy

	Abstract

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We have previously shown in transgenic mice that transforming growth factor (TGF)- dramatically enhances c-myc-induced hepatocarcinogenesis by promoting proliferation and survival of hepatocellular carcinoma (HCC) cells. As transgenic livers display increased levels of mature TGF-ß1 from the early stages of hepatocarcinogenesis, we have now assessed whether impairment of TGF-ß1 signaling contributes to the deregulation of cell cycle progression and apoptosis observed during this process. Focal preneoplastic lesions lacking expression of TGF-ß receptor type II (TßRII) were detected in c-myc/TGF- but not in c-myc livers. In c-myc/TGF- mice, 40% (2/5) of adenomas and 90% (27/30) of HCCs showed down-regulation of TßRII expression in comparison with 11% (2/18) of adenomas and 47% (14/30) of HCCs in c-myc mice. Down-regulation of the TGF-ß1-inducible p15^INK4B mRNA and reduced apoptotic rates in TßRII-negative HCCs further indicated the disruption of TGF-ß1 signaling. Furthermore, both TßRII-negative and -positive c-myc TGF- HCCs, but not c-myc HCCs, were characterized by decreased levels of the cell cycle inhibitor p27. These results suggest 1) an inverse correlation of decreased p27 expression with the particularly strong expression of TGF- in these lesions, consistent with the capacity of TGF- signaling to post-transcriptionally regulate p27, and 2) the presence of alternative, downstream defects of TGF-ß1 signaling in c-myc/TGF- HCCs that may impair the growth-inhibitory response to TGF-ß1. Thus, the accelerated neoplastic development in c-myc/TGF- mice is associated with an early and frequent occurrence of TßRII-negative lesions and with reduced levels of p27 in HCC cells, indicating that disruption of TGF-ß1 responsiveness may play a crucial role in the enhancement of c-myc-induced hepatocarcinogenesis by TGF-.

	Introduction

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The data summarized above provide indirect evidence for a progressive loss of sensitivity to TGF-ß1 during hepatocarcinogenesis in c-myc and c-myc/TGF- mice. In epithelial cells, including hepatocytes, TGF-ß1 inhibition of cell cycle progression is due to transcriptional down-regulation of proliferation-associated genes^9,10 and to inhibition of cyclin-dependent kinase (CDK) activities by induction/regulation of the CDK inhibitors (CDKIs) p15, p27, and p21.^10-15 These mechanisms contribute to maintaining the retinoblastoma protein (pRb) in hypophosphorylated form, a process critical for the growth-suppressive function of TGF-ß1.¹⁶ However, pRb was hyperphosphorylated in c-myc and c-myc/TGF- HCCs.⁵ In addition, many of the genes transcriptionally inhibited by TGF-ß1, such as endogenous c-myc,⁹ TGF-,¹⁷ cyclins D1 and A,^9,10,18 and E2F-1 and -2¹⁹ were induced,^2,5 indicating that the increased levels of TGF-ß1² were unable to block proliferation in the transformed cells. This interpretation is consistent with the observations that deregulated expression of c-myc, cyclin D1, or E2F is able to overcome TGF-ß1-mediated growth inhibition.^9,19,20

Given the presence of increased levels of mature TGF-ß1 from the early stages of hepatocarcinogenesis in mice co-expressing c-myc and TGF- transgenes,² we have investigated whether impairment of TGF-ß1-mediated growth-suppressive pathways may constitute a part of the multistage process of hepatocarcinogenesis in this transgenic model.⁵

	Materials and Methods

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Transgenic Mice and Tissue Preparation

Generation of the Alb-c-myc (c-myc) single-transgenic and Alb-c-myc/MT-TGF- (c-myc/TGF-) double-transgenic mice, transgene expression pattern, and pathological changes were as reported before.^2,4 In the current study, only male mice were investigated due to a more rapid neoplastic development culminating in appearance of HCC after a latency of 4 months in c-myc/TGF- mice and of more than 12 months in c-myc mice.² No tumors were observed in age-matched (C57BL/6J x CBA/J) x CD1 wild-type (wt) mice used as controls. Nontumorous liver lobes, individual tumors 5 mm, and separately microdissected peritumorous tissues were snap-frozen in liquid nitrogen and stored at -80°C until further use. Animal housing and care were in accordance with NIH guidelines.

Northern Blot Analysis

Ten micrograms of poly(A)+ RNA isolated from nontumorous, tumorous, and corresponding peritumorous tissues, was electrophoresed and blotted as described previously.^2,5 Blots were probed with ³²P-labeled cDNA probes, including a 1.3-kb fragment of mouse p15^INK4B,²¹ kindly provided by Dr. C.J. Sherr (St. Jude Children's Research Hospital, Memphis, TN), and a PCR-generated 0.35-kb fragment of mouse ribosomal protein L7 (rpL7) used to normalize RNA expression levels. The latter were visualized and quantified by PhosphorImager scanning and ImageQuant software (Molecular Dynamics, Sunnyvale, CA) as described.⁵ Differences (mean ± SE) were analyzed by unpaired t-test and considered significant when the two-tailed P value was <0.05.

Western Blot Analysis

This was performed essentially as reported before.⁵ Briefly, 0.3 g of non-neoplastic, neoplastic, and corresponding perineoplastic liver samples were homogenized in ice-cold lysis buffer containing 30 mmol/L Tris, pH 7.5, 150 mmol/L NaCl, 1% Nonidet P-40, 0.5% sodium deoxycholate, 0.1% SDS, 10% glycerol, 5 mmol/L EDTA, 1 mmol/L Na₃ VO₄, 20 mmol/L inorganic pyrophosphate, 1 mmol/L phenylmethylsulfonyl fluoride, 10 µg/ml aprotinin, and 10 µg/ml leupeptin. After an incubation of 15 minutes on ice, homogenates were sonicated three times for 10 seconds each and centrifuged to eliminate insoluble debris. Protein concentrations in the clarified supernatants were measured with Bio-Rad protein assay kit (Bio-Rad, Hercules, CA), 100 µg of total lysate proteins solubilized in boiling Laemmli buffer containing ß-mercaptoethanol were separated by 12% SDS-polyacrylamide gel electrophoresis, transferred to nitrocellulose membranes, and reacted with 1 µg/ml rabbit polyclonal anti-p27 antibody (Ab N-20; Santa Cruz Biotechnology, Santa Cruz, CA). The specificity of the reaction was tested by preincubating the primary Ab with the corresponding p27 control peptide (1:20 w/w; Santa Cruz). Equal loading conditions were confirmed by staining the membranes with Ponceau-S.

Immunohistochemistry

Immunohistochemistry (IHC) was performed on formalin-fixed, paraffin-embedded 5-µm sections from non-neoplastic liver lobes, from livers containing foci and benign tumors, and from 30 c-myc and 30 c-myc/TGF- HCCs and their corresponding adjacent tissues. Immunostainings for TßRII and I using Abs against the cytoplasmic kinase domain of either receptor (L-21 and V-22, respectively; Santa Cruz) have been reported previously.^3,8 Immunoreactivity was revealed with the Vectastain ABC Elite kit followed by Vector VIP peroxidase substrate (Vector Laboratories, Burlingame, CA), a reddish chromogen. Sections were then lightly counterstained with hematoxylin. In each run, sections reacted with primary Abs preadsorbed to corresponding immunogen peptides (Santa Cruz) showed no evidence of staining, thereby verifying the reaction specificity. Twenty random fields/section were examined with a x200 magnification by two pathologists and immunostainings arbitrarily scored as follows: -, when absent; +, when <5% of cells in the section were positive; ++, when 5% to 50% of cells were positive; +++, when >50% were stained.

	Results

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Overexpression of TGF-ß1 and Down-Regulation of TßRs during Hepatocarcinogenesis in c-myc and c-myc/TGF- Transgenic Mice

Our previous in situ hybridization and IHC studies showed that hepatocarcinogenesis in c-myc and c-myc/TGF- mice is characterized by strong autocrine up-regulation of mature TGF-ß1 associated with growth inhibition and apoptosis of dysplastic hepatocytes.^2,5

To address the possibility that these conditions may favor the selection of cells unresponsive to TGF-ß1, we analyzed the expression of the transmembrane TßRII during hepatocarcinogenesis in the two transgenic lines. Upon ligand binding, the serine-threonine kinase TßRII recruits and phosphorylates TßRI, which consequently becomes active and propagates TGF-ß1 signals to downstream effectors.^22,23 To study the expression pattern of TßRs we employed an immunohistochemical procedure previously used in other transgenic mouse hepatocarcinogenesis models.^3,8 Nontumorous and peritumorous transgenic tissues showed a more intense, albeit nonuniform, TßRII immunostaining than age-matched wt livers (data not shown). However, in c-myc/TGF- livers not yet populated by frank tumors, we observed small focal lesions with decreased expression of TßRII (Figure 1A) . These early TßRII-negative cell clusters consisted of cells, apparently diploid, smaller than dysplastic hepatocytes and with a basophilic or basophilic-clear cell phenotype² and represented only a subset (15/80, 19%) of the preneoplastic foci analyzed in the double-transgenic livers. Interestingly, these foci were characterized by a much lower apoptotic activity and increased mitosis when compared with TßRII-positive foci, which were composed of large, polymorphic, eosinophilic cells.^2,5,8 In addition, in c-myc/TGF- mice, two of five (40%) hepatocellular adenomas (HCAs) examined, both of basophilic phenotype, showed reduced TßRII expression. The extremely rapid HCC development in the double-transgenic mice² prevented us from staining a more informative number of benign tumors. Importantly, however, the vast majority (27/30, 90%) of c-myc/TGF- HCCs displayed down-regulation of TßRII expression as compared with adjacent parenchyma (Figure 1, B–D ; Table 1 ), implying the possibility of a selection and expansion of TßRII-negative cells during tumor progression. We did not detect TßRII-negative preneoplastic cell clusters in c-myc livers. Decreased TßRII immunoreactivity was observed in 11% (2/19) of c-myc HCAs and in 47% (14/30) of c-myc HCCs (Table 1) , indicating that loss of TßRII during neoplastic development in c-myc transgenic livers is a slower and less frequent event. Notably, a significant number of HCCs in c-myc/TGF- but not in c-myc mice, exhibited down-regulation of both TßRII and TßRI immunostaining (Table 1) , consistent with c-myc/TGF- HCCs being biologically more aggressive than c-myc HCCs.² Indeed, all of the TßRI-negative HCCs were poorly differentiated and highly invasive lesions composed of anaplastic cells and neovascular structures that totally replaced the hepatic parenchyma and infiltrated adjacent organs. Also remarkable was that HCCs with loss of TßRs were particularly rich in mitotic figures (Figure 1D) and, according to our previous observations,⁵ were characterized by apoptotic rates ~10-fold lower than those in TßRII-positive HCCs. In keeping with this, TßRII-negative HCCs were bigger than their TßRII-positive counterparts (average size 2.2 x 1.9 ± 0.6 x 0.8 cm versus 1.3 x 1 ± 0.2 x 0.3 cm) and appeared more vascularized due to sinousoid dilation, proliferation of neocapillaries, and presence of unaccompanied arteries. These data support the notion that escape from TGF-ß1 inhibitory effects may represent a major growth advantage for transformed cells in the transgenic livers.

View larger version (126K): [in this window] [in a new window]   Figure 1. Expression patterns of TßRII during hepatocarcinogenesis in c-myc/TGF- transgenic mice. Immunostaining was performed with an Ab against TßRII and VIP peroxidase substrate, a dark reddish chromogen, followed by light counterstaining with hematoxylin. A: Representative immunostaining of a 3-month-old c-myc/TGF- preneoplastic liver showing a small TßRII-negative cell cluster marked by arrows. Note that the cells composing the cluster are all of similar small size and apparently diploid as opposed to the intensely reddish (TßRII-positive), large, and polymorphic dysplastic hepatocytes in surrounding parenchyma. Magnification, x200. Serial section reacted with the primary Ab preincubated with a control peptide (inset) shows no immunostaining. B to D: Examples of TßRII down-regulation in neoplastic lesions. Tumor cells show no staining or very weak staining, in contrast to the prominent immunoreactivity of nontumorous surrounding parenchyma in a 6-month-old mouse (B; x60). Peritumorous cells show intense, albeit heterogeneous, TßRII immunostaining as compared with the weak immunoreactivity of cells in a tumor marked by arrows (C; x125). A HCC showing total lack of TßRII immunostaining and several mitotic figures (thin arrows) in an 8-month-old mouse (D; x200).

View this table: [in this window] [in a new window]   Table 1. Differential Expression of TGF-ß1, TßRI, and TßRII in Peritumorous Tissues (PT), Preneoplastic Foci, HCAs and HCCs of c-myc and c-myc/TGF- Transgenic Mice As Assessed by Immunohistochemical Staining

To better assess the impact of TßRII down-modulation on TGF-ß1-regulated growth-inhibitory pathways, we analyzed mRNA expression of p15^INK4B, a TGF-ß1-inducible gene encoding a specific CDK4/6 inhibitor that causes G1 arrest in human and mouse epithelial cells.^11,21 p15^INK4B mRNA expression levels correlated with TßRII immunoreactivity during transgene-induced hepatocarcinogenesis (Figure 2) . The steady-state level of p15^INK4B transcript was higher in transgenic than age-matched wt livers (Figure 2) , consistent with the induction of TGF-ß1 and TßRII in transgenic mice. More importantly, the c-myc and c-myc/TGF- HCCs that retained TßRII expression displayed levels of p15^INK4B mRNA comparable to those in the corresponding peritumorous tissues. In contrast, HCCs with significant reduction or total loss of TßRII showed significant down-regulation of p15^INK4B mRNA as compared with the adjacent tissues (Figure 2) .

View larger version (49K): [in this window] [in a new window]   Figure 2. Northern blot analysis of p15INK4B mRNA expression and its correlation with TßRII status during hepatocarcinogenesis in c-myc/TGF- and c-myc transgenic mice. A: Representative example of steady-state p15INK4B mRNA levels in transgenic mice. Poly(A)+ RNA was obtained from wt liver (wt) and from nontumorous (N), peritumorous (P), and tumorous (T) tissues in c-myc/TGF- and c-myc livers. +, HCCs expressing TßRII at levels comparable to those in the corresponding peritumorous tissues when assessed by IHC; -, HCCs with reduced or absent TßRII expression. Note, as an interesting example, the differential p15INK4B mRNA expression in a TßRII-negative HCC and in a TßRII-positive HCC isolated from the same c-myc/TGF- mouse, labeled as 3. B: Quantitation of PhosphorImager-scanned Northern blots for p15INK4B mRNA expression in peritumorous tissue (PT, hatched bars), TßRII-positive HCCs (black bars), and TßRII-negative HCCs (white bars) of c-myc and c-myc/TGF- mice. Scans were normalized to rpL7 and quantitated by ImageQuant software.

Selective Reduction of p27 Protein in c-myc/TGF- HCCs

We next compared nontumorous and tumorous tissues with respect to the abundance of another important mediator of the growth-inhibitory response to TGF-ß1, the CDKI p27.^12-15 Indeed, once induced by TGF-ß1 in epithelial cells, p15 binds to and inhibits cyclin-D-dependent kinases, thereby promoting the redistribution of p27 from cyclin D-CDK4/6 complexes to cyclin E- and cyclin A-CDK2, resulting in inhibition of their kinase activity.¹⁵ As illustrated in Figure 3 , immunoblot analysis of liver homogenate proteins showed higher levels of p27 in nontumorous transgenic tissues than in wt livers. This conceivably reflects the TGF-ß1 up-regulation in nontumorous tissues, as TGF-ß1 is capable of increasing p27 abundance in certain cell types.^12-15 However, c-myc/TGF- HCCs displayed a remarkable down-modulation of p27 expression as compared with the corresponding adjacent tissues and with c-myc HCCs (Figure 3) . This decrease of p27 abundance in c-myc/TGF- HCCs was unrelated to the TßRII status in the lesions, as it was also detected in the few TßRII-positive HCCs of double-transgenic mice. Conversely, it was not detected in TßRII-negative HCCs of c-myc mice. These findings suggest that factors such as the very strong expression of TGF- in c-myc/TGF- HCCs and their poor differentiation grade² may modulate p27 expression. These results also raise the possibility that neoplastic cells with reduced levels of p27 may be less responsive to TGF-ß1-mediated cell cycle arrest even when they retain expression of TßRs.

View larger version (20K): [in this window] [in a new window]   Figure 3. Representative Western blot showing p27 down-regulation in c-myc/TGF- HCCs but not in c-myc HCCs. Total liver protein was extracted and used for Western analysis as described in Materials and Methods. N, nontumorous tissue in wt liver; P, peritumorous tissue; T, tumor. Samples in lanes 3 and 9 were obtained from TßRII-positive HCCs whereas those in lanes 5 and 7 were from TßRII-negative HCCs.

	Discussion

Top Abstract Introduction Materials and Methods Results Discussion References

TßRII-negative preneoplastic cell clusters were not detected in c-myc livers, whereas TßRII down-regulation was observed in only 11% and 47% of c-myc HCAs and HCCs, respectively. Thus, selection and expansion of cells that become insensitive to TGF-ß1 by losing the expression of TßRII occur less frequently and at later stages during c-myc-induced hepatocarcinogenesis. This observation is consistent with the much slower tumor development in c-myc mice as compared with that in c-myc/TGF- mice² and with the concept that loss of TGF-ß1 responsiveness contributes to malignant progression. However, the emergence of TßRII-positive tumors in single- and, to a lesser extent, double-transgenic mice suggests the possible involvement of alternative mechanisms of TGF-ß1 resistance in these lesions. In this respect, mutations of the insulin-like growth factor II receptor (IGFIIR), involved in TGF-ß activation,^34-36 or mutations of the SMAD genes encoding the transducers of TßR kinase activity,^22,23 or overexpression of proteins that disrupt TGF-ß-mediated cell cycle control by interacting with pRb,³⁷ have recently been described in human and experimental tumors, including HCCs.^35-37 Whether one or more of these mechanisms is/are present during the neoplastic process in the transgenic livers is currently a matter of investigation in our laboratory. It is also plausible that the constitutive expression of the c-myc transgene may represent itself a potential mechanism of TGF-ß resistance as c-myc is one of the main transcriptional targets for TGF-ß.⁹ In any event, our current data imply that co-expression of TGF- and c-myc results in early inactivation of TßRII during neoplastic development. This notion is supported by the frequency of HCCs showing TßRII down-modulation that increases from <50% in c-myc/TGF-ß1⁸ and c-myc (this report) transgenic mice, in which HCCs appear after a latency of 12 months,^2,3,8 to 90% in c-myc/TGF- mice (this report), which develop HCCs after 4 months.² Thus, in addition to TGF-ß1 up-regulation, co-expression of c-myc and TGF- may provide cooperating signals resulting in selection of transformed cells with reduced TßRII expression and in enhanced tumor progression in the liver. Notably, overexpression of cyclin D1, a striking feature of c-myc/TGF- HCCs,⁵ was shown to decrease TßRII expression.²⁰

The selective reduction of p27 expression in c-myc/TGF- HCCs reported in this study may also correlate with loss of response to TGF-ß1, as inhibition of epithelial cell cycle progression by this cytokine relies, in part, on p27 activities.^12-15 It has been recently shown in mice that p27 may act as an inhibitor of CDK2 activity in the regenerating liver³⁸ and that the p27^Kipl gene is haplo-insufficient for tumor suppression.³⁹ This implies that reduced levels of p27 protein may predispose to abnormal cell cycle and tumor progression, particularly when p27 function could be already counteracted, at least in part, by the overexpression of c-myc,⁴⁰ cyclins,³⁹ and E2F occurring during c-myc/TGF--induced hepatocarcinogenesis.^2,5 Our hypothesis is supported by the findings that p27 heterozygous mice are predisposed to physically, chemically, or spontaneously generated tumors³⁹ and that in several human epithelial cancers the amount of p27 protein expression inversely correlates with tumor aggressiveness and patient mortality.^41-43 Despite unaltered p27^Kipl mRNA expression, the most aggressive tumors displayed high p27 proteolytic degradation,^42,43 consistent with the evidence that cellular abundance of this CDKI is controlled post-transcriptionally.^44,45 That p27 levels may be analogously regulated in c-myc/TGF- HCCs is suggested by the preserved expression of p27^Kipl mRNA in these lesions (E. Santoni-Rugiu, M.R. Jensen, and S.S. Thorgeirsson, unpublished) and by the high aggressiveness and poor differentiation of these tumors compared with HCCs in c-myc² or other transgenic mice (reviewed in Santoni-Rugiu and Thorgeirsson⁴⁶). Indeed, activation of the Ras/mitogen-activated protein kinase (MAPK) pathway by several growth factors, including TGF-,⁴⁷ can cause reduction of p27 levels by decreasing translation and stability of the protein (reviewed by Lloyd⁴⁸). We cannot exclude that down-regulation of p27 may also represent a survival advantage for c-myc/TGF- HCCs, as excessive overexpression of p27 was reported to induce apoptosis in normal and neoplastic cells.^49,50

It is noteworthy that the reduction of p27 abundance was independent of TßRII levels in the HCCs, as it was also detected in the few TßRII-positive HCCs of c-myc/TGF- mice and not detected in TßRII-negative HCCs of c-myc mice. Although this supports the notion that the very strong TGF- expression and the poor differentiation grade of c-myc/TGF- HCCs² may play the most important role in modulating p27 expression in these lesions, it also suggests that p27 may have other functions in modulating cell proliferation on its own. This is in line with the fact that cells from p27^Kipl nullizygous mice are still partially responsive to TGF-ß-induced growth arrest.⁵¹ Therefore, inactivation of TßRII represents a more effective way for circumventing TGF-ß growth-suppressive function and consequently is frequently selected for in c-myc/TGF--induced hepatocarcinogenesis.

In conclusion, we have shown that the acceleration of c-myc-induced hepatocarcinogenesis by co-expression of TGF- is associated with an earlier and more frequent occurrence of TßRII-negative lesions and with reduced levels of p27 in HCC cells, indicating that disruption of TGF-ß1 signaling may play a crucial role in the promotion and progression of liver cancer.

	Acknowledgements

 
We are grateful to Dr. G. Merlino for providing the TGF- transgenic mice, Dr. C. J. Sherr for the gift of p15INK4B cDNA, Dr. H. C. Bisgaard for helpful suggestions, and N. Sanderson and A. Ton for excellent technical assistance. Financial support from the Danish Cancer Society to M. R. Jensen is gratefully acknowledged.

	Footnotes

 
Address reprint requests to Dr. Snorri S. Thorgeirsson, National Cancer Institute, Bldg. 37, Room 3C28, 37 Convent Drive MSC4255, Bethesda, MD 20892-4255. E-mail: snorri_thorgeirsson{at}nih.gov

Present address for E. Santoni-Rugiu: Danish Cancer Society, Department of Cell Cycle and Cancer, Strandboulevarden 49, 2100 Copenhagen Ø, Denmark.

Accepted for publication March 6, 1999.

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