QUICK SEARCH:   [advanced] Author: Keyword(s): Year:  Vol:  Page:

This Article Abstract Full Text (PDF) Supplemental Research Data Alert me when this article is cited Alert me if a correction is posted Citation Map Services Email this article to a friend Similar articles in this journal Similar articles in PubMed Alert me to new issues of the journal Download to citation manager Citing Articles Citing Articles via HighWire Citing Articles via Google Scholar Google Scholar Articles by Oskarsson, T. Articles by Trumpp, A. Search for Related Content PubMed PubMed Citation Articles by Oskarsson, T. Articles by Trumpp, A. Social Bookmarking                   What's this?

RESEARCH COMMUNICATION

Skin epidermis lacking the c-myc gene is resistant to Ras-driven tumorigenesis but can reacquire sensitivity upon additional loss of the p21^Cip1 gene

¹ Genetics and Stem Cell Laboratory, Swiss Institute for Experimental Cancer Research (ISREC) Ch. des Boveresses 155, 1066 Epalinges, Switzerland; ² Ecole Polytechnique Fédérale de Lausanne (EPFL), School of Life Sciences, 1015 Lausanne, Switzerland; ³ Institut de Génétique et de Biologie Moléculaire et Cellulaire and Institut Clinique de la Souris, 67404 Illkirch, France; ⁴ Department de Pharmacologie et de Toxicologie, Université de Lausanne, 1005 Lausanne, Switzerland

	Abstract

Top Abstract Results and Discussion Materials and methods Acknowledgments References

 
The target gene(s) required for Myc-mediated tumorigenesis are still elusive. Here we show that while endogenous c-Myc is surprisingly dispensable for skin homeostasis and TPA-induced hyperplasia, c-Myc-deficient epidermis is resistant to Ras-mediated DMBA/TPAinduced tumorigenesis. This is mechanistically linked to p21^Cip1, which is induced in tumors by the activated Ras–ERK pathway but repressed by c-Myc. Acute elimination of c-Myc in established tumors leads to the up-regulation of p21^Cip1, and epidermis lacking both p21^Cip1 and c-Myc reacquires normal sensitivity to DMBA/TPA-induced tumorigenesis. This identifies c-Myc-mediated repression of p21^Cip1 as a key step for Ras-driven epidermal tumorigenesis.

[Keywords: c-Myc; p21^Cip1; epidermal tumorigenesis; DMBA/TPA]

Received January 24, 2006; revised version accepted May 28, 2006.

In the mammalian skin epidermis, c-Myc is expressed in the basal layer and the hair bulb, as well as the bulge region correlating with the proliferative and stem cell-containing portion of the skin epidermis (Hurlin et al. 1995; Bull et al. 2001). Ectopic overexpression of c-Myc using the involucrin or keratin-5 promoter leads to hyperplasia and eventual tumorigenesis including invasive squamous cell carcinomas (SCCs) (Pelengaris et al. 1999; Rounbehler et al. 2001).

However, overexpression of c-Myc using the keratin-14 promoter results in an initial phase of hyperplasia but ultimately leads to a keratinocyte-migration defect, increased size of sebaceous glands, and depletion of label-retaining cells accompanied by partial epidermal loss in areas of mechanical stress. This phenotype is thought to be caused by promotion of epidermal stem cells to differentiate into interfollicular epidermis and sebaceous glands at the expense of hair-follicle differentiation and stem-cell maintenance (Arnold and Watt 2001; Waikel et al. 2001; Murphy et al. 2005).

On its own, c-Myc is unable to transform normal cultured cells. However, c-Myc has been shown to cooperate with the Ras oncoprotein to transform immortalized cells (Land et al. 1983). The nature of this cooperation is not well understood, but c-Myc is thought to counteract cell-cycle arrest induced by ectopic Ras expression in primary cells. Conversely, Ras has been shown to stabilize the labile c-Myc protein (Sears 2004) and is thought to inhibit c-Myc-induced apoptosis through activation of the PI3-kinase pathway (Kauffmann-Zeh et al. 1997). In this study we demonstrate that c-Myc is essential for cell cycle progression of cultured fibroblasts and keratinocytes but, in contrast, is dispensable for epidermal homeostasis in vivo. Most importantly, we show that c-Myc is required for H-Ras-induced epidermal tumorigenesis and that this is mechanistically linked to the activity of c-Myc to repress the CDK inhibitor p21^Cip1.

	Results and Discussion

Top Abstract Results and Discussion Materials and methods Acknowledgments References

 
To study whether the role of c-Myc is similar in cultured fibroblastic and epithelial cell types, we prepared 3T9 fibroblasts and normal keratinocytes from mice homozygous for the conditional c-myc^flox allele (Trumpp et al. 2001). Inducible conversion of the c-myc^flox allele into the c-myc^ORFrec-null allele (Fig. 1A) was achieved via an inducible MSCV-based retroviral system carrying a 4-hydroxy-tamoxifen (4OHT)-inducible Cre recombinase (Supplemental Fig. [S] 1; Indra et al. 1999). Addition of 4OHT to the medium of cells carrying this construct efficiently leads to the disappearance of detectable c-Myc protein in 3T9 fibroblasts and normal keratinocytes within 24 h (Figs. S2, S3). Upon loss of c-Myc expression, both cell types ceased proliferation, accumulated in a Ki67^neg (G₀) stage, and acquired a flat-cell phenotype with an altered F-actin distribution (Figs. S2, S3). In addition, 96 h post-c-myc deletion, keratinocytes turn on the senescence-associated -galactosidase (SA--gal) activity (Dimri et al. 1995), indicating that c-Myc activity is essential to prevent premature senescence in these cells (Fig. S4). In summary, these data show that similar to what we and others have suggested for cultured fibroblasts (de Alboran et al. 2001; Holzel et al. 2001; Trumpp et al. 2001; Guney et al. 2006; Prathapam et al. 2006), c-Myc activity in keratinocytes is essential for inhibiting premature senescence and maintaining cells in a productive cell cycle.

To address whether c-Myc is required for keratinocyte proliferation in vivo, we used the K5CreER^T mouse strain to conditionally eliminate the c-myc^flox gene in the basal layer of the epidermis, hair follicle outer root sheath, sebaceous glands, and the hair follicle bulge region (Indra et al. 1999). After weaning, K5CreER^T;c-myc^flox/flox or K5CreER^T;c-myc^ORF/flox mice (mutant) and c-myc^floxflox, c-myc^ORF/flox or K5CreER^T;c-myc^flox/+ mice (control) were injected with tamoxifen for 5 consecutive days. Assessment of the recombination efficiency in the epidermis was determined by Southern blot analysis (Fig. 1B) and real-time Taqman PCR, and revealed 81.3% ± 11% recombination at 3 wk and 88.3% ± 3% 20 wk after tamoxifen induction, suggesting that no selection against c-myc-deficient cells occurred in the mouse epidermis over time. In addition, as epidermal stem cells are the only epidermal cells with a long half-life, it is likely that most of these cells exhibit c-myc deletion as well.

View larger version (92K): [in this window] [in a new window]   Figure 1. Induced deletion of the c-myc gene in the adult mouse epidermis. (A) Schematic figure showing the conditional c-mycflox allele. Exons are indicated as boxes 1–3. The entire open reading frame (ATG to Stop [yellow region]) is flanked by loxP sites (black triangles). Restriction sites and probe (blue oval) used for Southern blot analysis are indicated. (B) Southern blot showing recombination at the c-myc locus in K5CreERT;c-mycORF/flox (mutant M1, M2) and control (C1, c-mycflox/KO; C2, c-mycflox/flox) epidermis 20 wk after tamoxifen induction. (C,D) Hematoxilin and Eosin staining of sections obtained from control and mutant dorsal skin. (E) Epidermis, (D) dermis, (HF) hair follicles, (Sb) sebaceous glands. Magnification, 20x. (E,H) Immunohistochemical analysis of the proliferation marker Ki67 in the whiskers area (E,F) and BrdU incorporation in dorsal skin (G,H). Arrows indicate examples of Ki67-expressing and BrdU-positive cells. Insets show an area of higher magnification. Magnification, 40x. (I–N) Immunohistochemical analysis of differentiation markers revealed no difference between control and c-Myc mutant epidermis. (I,J) Keratin 14 ([K14] green) expression in skin of the whisker area, (blue) DAPI. (K,L) Keratin 1 ([K1] red) expression in the whisker area. Arrows indicate K1-negative hair follicles. (M,N) K1 expression showing the K1-negative basal layer (arrows).

To further address the role of c-Myc during epidermal proliferation in response to stress conditions, skin was treated with 12-O-tetradecanoylphorbol–13-acetate (TPA). This phorbol ester induces a robust proliferative response leading to substantial epidermal hyperplasia in a matter of days, known to be associated with high expression of c-Myc (Kennard et al. 1995). Surprisingly, control and mutant skin developed comparable epidermal thickening (Fig. 2A–D) and a similar increase in BrdU incorporation (Fig. 2E–J), suggesting that endogenous c-Myc is not required for TPA-induced epidermal hyperplasia. In summary, these data suggest that c-Myc is not required for proliferation, growth, and differentiation of the adult mouse epidermis and is therefore dispensable for skin epidermal homeostasis and TPA-induced hyperplasia. This result is surprising considering the expression of this gene in the basal layer, bulge, and hair bulb (Hurlin et al. 1995; Bull et al. 2001), and with respect to our findings showing that c-Myc is essential to maintain proliferation of cultured keratinocytes. A recent study on c-Myc-deficient epidermis using a noninducible K5Cre transgenic line showed decrease in cellularity presumably caused by premature keratinocyte differentiation and a defect in cell growth (Zanet et al. 2005). The reason for this apparent discrepancy is unclear; however, one possible explanation may be the use of a noninducible transgene that already eliminates c-Myc during embryogenesis (Zanet et al. 2005) rather than in the adult epidermis. In support of this possibility, we have recently demonstrated distinct roles for c-Myc during development and adult homeostasis in the intestinal epithelium (Bettess et al. 2005).

View larger version (102K): [in this window] [in a new window]   Figure 2. TPA-induced epidermal hyperplasia occurs to a similar extent in control and c-Myc-deficient skin. (A,D) Hematoxilin and Eosin staining of dorsal skin taken from the same individuals either from treated or untreated area of the back skin. Thickness of epidermis (Epi) is indicated. (E,J) Immunohistochemical analysis of BrdU incorporation. Arrows indicate examples of BrdU-positive cells; arrows in I and H indicate BrdU-positive suprabasal cells. Original magnification: 20x.

The development of these tumors is dependent on oncogenic Ras activity, and 90% of these tumors have been shown to select for an AT182 mutation in the Harvey-Ras (H-Ras) gene (Quintanilla et al. 1986). In this respect, it is important to note that Ras and Myc comprise the first example of oncogene cooperation during the cellular transformation process (Land et al. 1983). In addition, recent findings suggest that the Ras-ERK pathway can stabilize the labile c-Myc protein (Sears 2004; Adhikary and Eilers 2005), thus we hypothesized that a functional endogenous c-myc gene might be necessary for Ras-driven tumorigenesis. To address this, adult control and mutant mice were first injected with tamoxifen to induce c-myc^flox excision followed by treatment with DMBA/TPA (see Materials and Methods for details). Consistent with previous studies (for review, see Kemp 2005) papillomas became evident 5–6 wk after TPA promotion. On average, 30 papillomas/mouse developed in controls (Fig. 3A–C), of which the vast majority contained the AT182 mutation in H-Ras (see below). Although the onset of tumor formation was similar in mutant mice (Fig. 3A), the number of tumors was strongly reduced (Fig. 3B). Indeed, in some mutants, tumor formation was negligable (Fig. 3C, arrowhead). The tumors that formed in mutant mice were very similar with respect to size, histology, and proliferative activity as estimated by BrdU incorporation compared with those formed in control mice (Fig. 3; data not shown). In addition, the percentage of the A T182 mutation in the H-Ras gene was found to be comparable (83% in tumors on control mice [10/12] vs. 86% in tumors on mutants [31/36]) (Fig. 4F). However, subsequent genotyping of the papillomas grown on mutant skin by Taqman real-time PCR showed that none of these tumors (n = 24) contained the recombined c-myc^ORFrec-null allele (Figs. 1A, 3D). Thus, tumors grown on the mutant epidermis have originated from cells that escaped recombination and strongly suggest that tumors specifically selected against c-Myc deficient cells. Hence, the endogenous c-myc gene is essential for Ras-driven epithelial tumorigenesis triggered by the DMBA/TPA protocol.

View larger version (54K): [in this window] [in a new window]   Figure 3. c-Myc mutant skin is resistant to chemical carcinogenesis. (A) Kinetics of tumor incidence in control and c-Myc-deficient (mutants) epidermis. (B) Tumor number per mouse. Mutants, n = 17; controls, n = 9. (C) Typical examples of control and mutant mice after 11 wk of TPA promotion. Arrows point to typical papillomas, arrowhead points to tumor-free skin. (D) Analysis of Cre-mediated recombination at the c-myc locus in tumors developed in mutant mice. Real-time Taqman PCR analysis detecting the c-mycORFrec allele on DNA isolated from tumors and epidermis isolated from mutant mice. DeltaCt indicates the additional number of PCR cycles needed to detect the product in relation to the control with 90% deletion, which was set to 1. Samples with a relative c-mycORFrec content of 0%, 45%, and 90% (as determined by Southern blot) were used as references. (T1–T24) DNA from 24 tumors. The line dividing the graph indicates a c-mycORFrec content of 1.4%.

View larger version (74K): [in this window] [in a new window]   Figure 4. Acute deletion of the c-myc gene in established papillomas causes up-regulation of p21Cip1. Immunohistochemical analysis of p21Cip1 expression in established tumors of control (A) and mutant (B) animals 11 d after the last tamoxifen treatment (arrows indicate examples of p21Cip1-expressing nuclei). (C,D) Lack of p21Cip1 expression in hyperplastic epidermis located adjacent to the tumors shown in A and B. (E) Western blot analysis showing the level of phophorylated ERK (P-ERK), total ERK (ERK), and tubulin (loading control). (F) PCR–RFLP (restriction fragment length polymorphism) analysis detecting the A-T182 mutation in H-ras. (S) Skin between tumor, (T) tumor.

Ectopic Ras expression induces proliferation by induction of CyclinD1 and repression of p27^Kip1 (Pruitt and Der 2001). However, this cell cycle induction is coupled to the up-regulation of cell cycle inhibitors such as p15^INK4b, p16^INK4a, and p21^Cip1, which under certain conditions can lead to cell cycle arrest and senescence (Serrano et al. 1997; Dajee et al. 2003; Braig et al. 2005; Collado et al. 2005). In human fibroblasts and keratinocytes, p21^Cip1 has been reported to be a key inducer of cellular senescence in vitro (Brown et al. 1997; Sayama et al. 1999). Since the p21^Cip1 promoter is bound and repressed by the c-Myc/Miz-1 complex (Herold et al. 2002; Seoane et al. 2002), we hypothesized that c-Myc activity in tumors might be critical to prevent the expression of p21^Cip1. To address this possibility, we initiated tumor formation in nondeleted K5::CreER^T; c-myc^flox/flox mice and subsequently induced Cre activity by tamoxifen. Immunohistochemical analysis revealed strong up-regulation of the p21^Cip1 protein in tumors following acute deletion of c-myc (Fig. 4A,B). Interestingly, p21^Cip1 up-regulation is tumor-specific and is not observed in acutely deleted hyperplastic epidermis (in between papillomas) (Fig. 4C,D) or untreated skin (data not shown). This phenomenon correlates well with the differential activity of the Ras–ERK pathway. We found that the already high ERK phosphorylation in TPA-induced epidermis is further increased in papillomas (Fig. 4E), which is consistent with the presence of the mutated dominant active H-Ras allele in tumors but not hyperplastic epidermis (Fig. 4F).

To genetically test the hypothesis that p21^Cip1 is a key target that needs to be repressed by c-Myc during papilloma formation, K5::CreER^T; c-myc^flox/flox mice were bred onto a p21^Cip1-deficient background (Brugarolas et al. 1995) and double-mutant mice were treated with DMBA/TPA. Interestingly, homozygous (but not heterozygous) loss of p21^Cip1 restored normal tumor frequency in female epidermis lacking c-Myc (Fig. 5A,B). In agreement, the majority of double-mutant tumors lacked detectable c-Myc expression (Fig. 5C–F). These data show that while c-Myc-deficient tumors were never observed on a wild-type background, they do form in the additional absence of a functional p21^Cip1 gene. Collectively, these data provide genetic evidence that the key function for the oncogene c-Myc during epidermal tumorigenesis is the repression of the CDK inhibitor p21^Cip1. This seems to be a critical step only during tumorigenesis and not during homeostasis, since hyperactivation of the Ras–ERK pathway (which induces p21^Cip1) occurred only during the transition from TPA-induced hyperplasia to papillomagenesis. Uninhibited p21^Cip1 activity is known to efficiently block proliferation and/or senescence, thus providing an explanation for the resistance of c-Mycdeficient epidermis to Ras-driven tumorigenesis.

View larger version (85K): [in this window] [in a new window]   Figure 5. p21Cip1 deficiency restores tumorigenesis in c-Myc mutant mice. (A) Total tumor number in mutant and control females on p21+/– or p21–/– backgrounds. (Left) Blue control, n = 2; red mutant, n = 5. (Right) Blue control, n = 10; red mutant, n = 8. (B) Representative examples of female mice showing tumor restoration in epidermis lacking both c-Myc and p21Cip1. (C–F) Immunohistochemical analysis of c-Myc expression in tumors with the indicated genotype. The majority of tumors from K5CreERT; c-mycflox/flox;p21+/– epidermis are c-Myc positive (arrows) (C,D; n = 13). In contrast, in most restored tumors of the K5CreERT;c-mycflox/flox p21–/– genotype, c-Myc expression was not detected (E,F; n = 14). Note the white "holes" in most cells (examples indicated with arrowheads), which represent nuclei lacking c-Myc expression.

	Materials and methods

Top Abstract Results and Discussion Materials and methods Acknowledgments References

 

Mice

K5CreER^T; c-myc^flox/flox, or K5CreER^T; c-myc^flox/KO conditional knockout animals on a wild-type or p21^–/–-deficient background were generated using previously described alleles (Brugarolas et al. 1995; Indra et al. 1999; Trumpp et al. 2001). Three- to five-week-old mice were injected intraperitoneally with 1 mg of tamoxifen (dissolved in sunflower oil; Sigma) once a day for 5 or 10 d (consecutive). All experiments were approved by the Schweizer-Bundesamt-für-Veterinärwesen authorization number 1728.

DMBA/TPA treatment

TPA (Sigma) was applied on shaved back skin. Applications were 1–4 x 6.5 ug/mouse, and mice were sacrificed 1 d after the last application. For the two-stage carcinogenesis protocol, DMBA (Fluka) was applied in acetone on shaved dorsal skin 32 ug/mouse. Single DMBA treatment was followed by TPA applications (12.5 ug in acetone) two times per week.

Antibodies

Immunohistochemistry: Ki67 (Novocastra; 1:50), Keratin 14 (Covance, FITC-155L), Keratin1 (Covance, PRB-165P), p21 (Santa Cruz, sc-6246), anti-BrdU (Oxford Biotechnology), and c-Myc (Upstate Biotechnologies, 06-340). Western blot analysis: phosphospecific p44/42 MAPK-Thr202/Tyr204 and p44/42 MAPK antibody (Cell Signaling).

Detailed methods are published as supplemental information.

	Acknowledgments

Top Abstract Results and Discussion Materials and methods Acknowledgments References

 
We thank Dr. Tyler Jacks for providing the p21^CIP1 mutant mice and Drs. Paolo Dotto and Christelle Adolphe for critical comments on the manuscript. We thank Drs. Jörg Hülsken and Ilaria Malanchi for help with the two-stage carcinogenesis protocol and Dr. Hans Smola for help with histology. M.A.G.E. is the recipient of an EMBO long-term fellowship. This work was supported by grants to A.T. from the Swiss National Science Foundation, the Swiss Cancer League and the Leenards Foundation, and the EU-FP6 Program "INTACT." A.T. is a member of the EMBO Young Investigator Program.

	Footnotes

 
⁵ Corresponding author.

E-MAIL Andreas.Trumpp{at}isrec.ch; FAX 41-21-652-6933.

Supplemental material is available at http://www.genesdev.org.

Article is online at http://www.genesdev.org/cgi/doi/10.1101/gad.381206

	References

Top Abstract Results and Discussion Materials and methods Acknowledgments References

 
Adhikary S. and Eilers M. 2005. Transcriptional regulation and transformation by Myc proteins. Nat. Rev. Mol. Cell Biol. 6: 635–645.[CrossRef][Medline]

Arnold I. and Watt F.M. 2001. c-Myc activation in transgenic mouse epidermis results in mobilization of stem cells and differentiation of their progeny. Curr. Biol. 11: 558–568.[CrossRef][Medline]

Bettess M.D., Dubois N., Murphy M.J., Dubey C., Roger C., Robine S., Trumpp A. 2005. c-Myc is required for the formation of intestinal crypts but dispensable for homeostasis of the adult intestinal epithelium. Mol. Cell. Biol. 25: 7868–7878.[Abstract/Free Full Text]

Boukamp P. 2005. Non-melanoma skin cancer: What drives tumor development and progression? Carcinogenesis 26: 1657–1667.[Abstract/Free Full Text]

Braig M., Lee S., Loddenkemper C., Rudolph C., Peters A.H., Schlegelberger B., Stein H., Dorken B., Jenuwein T., Schmitt C.A. 2005. Oncogene-induced senescence as an initial barrier in lymphoma development. Nature 436: 660–665.[CrossRef][Medline]

Brown J.P., Wei W., Sedivy J.M. 1997. Bypass of senescence after disruption of p21CIP1/WAF1 gene in normal diploid human fibroblasts. Science 277: 831–834.[Abstract/Free Full Text]

Brugarolas J., Chandrasekaran C., Gordon J.I., Beach D., Jacks T., Hannon G.J. 1995. Radiation-induced cell cycle arrest compromised by p21 deficiency. Nature 377: 552–557.[CrossRef][Medline]

Bull J.J., Muller-Rover S., Patel S.V., Chronnell C.M., McKay I.A., Philpott M.P. 2001. Contrasting localization of c-Myc with other Myc superfamily transcription factors in the human hair follicle and during the hair growth cycle. J. Invest. Dermatol. 116: 617–622.[CrossRef][Medline]

Chan K.S., Sano S., Kiguchi K., Anders J., Komazawa N., Takeda J., DiGiovanni J. 2004. Disruption of Stat3 reveals a critical role in both the initiation and the promotion stages of epithelial carcinogenesis. J. Clin. Invest. 114: 720–728.[CrossRef][Medline]

Collado M., Gil J., Efeyan A., Guerra C., Schuhmacher A.J., Barradas M., Benguria A., Zaballos A., Flores J.M., Barbacid M. et al. 2005. Tumour biology: Senescence in premalignant tumours. Nature 436: 642.[CrossRef][Medline]

Dajee M., Lazarov M., Zhang J.Y., Cai T., Green C.L., Russell A.J., Marinkovich M.P., Tao S., Lin Q., Kubo Y. et al. 2003. NF-B blockade and oncogenic Ras trigger invasive human epidermal neoplasia. Nature 421: 639–643.[CrossRef][Medline]

de Alboran I.M., O’Hagan R.C., Gartner F., Malynn B., Davidson L., Rickert R., Rajewsky K., DePinho R.A., Alt F.W. 2001. Analysis of C-MYC function in normal cells via conditional gene-targeted mutation. Immunity 14: 45–55.[CrossRef][Medline]

Delgado M.D., Vaque J.P., Arozarena I., Lopez-Ilasaca M.A., Martinez C., Crespo P., Leon J. 2000. H-, K- and N-Ras inhibit myeloid leukemia cell proliferation by a p21WAF1-dependent mechanism. Oncogene 19: 783–790.[CrossRef][Medline]

Dimri G.P., Lee X., Basile G., Acosta M., Scott G., Roskelley C., Medrano E.E., Linskens M., Rubelj I., Pereira-Smith O. et al. 1995. A biomarker that identifies senescent human cells in culture and in aging skin in vivo. Proc. Natl. Acad. Sci. 92: 9363–9367.[Abstract/Free Full Text]

Grandori C., Cowley S.M., James L.P., Eisenman R.N. 2000. The Myc/Max/Mad network and the transcriptional control of cell behavior. Annu. Rev. Cell Dev. Biol. 16: 653–699.[CrossRef][Medline]

Guney I., Wu S., Sedivy J.M. 2006. Reduced c-Myc signaling triggers telomere-independent senescence by regulating Bmi-1 and p16(INK4a). Proc. Natl. Acad. Sci. 103: 3645–3650.[Abstract/Free Full Text]

Hermeking H., Rago C., Schuhmacher M., Li Q., Barrett J.F., Obaya A.J., O’Connell B.C., Mateyak M.K., Tam W., Kohlhuber F. et al. 2000. Identification of CDK4 as a target of c-MYC. Proc. Natl. Acad. Sci. 97: 2229–2234.[Abstract/Free Full Text]

Herold S., Wanzel M., Beuger V., Frohme C., Beul D., Hillukkala T., Syvaoja J., Saluz H.P., Haenel F., Eilers M. 2002. Negative regulation of the mammalian UV response by Myc through association with Miz-1. Mol. Cell 10: 509–521.[CrossRef][Medline]

Holzel M., Kohlhuber F., Schlosser I., Holzel D., Luscher B., Eick D. 2001. Myc/Max/Mad regulate the frequency but not the duration of productive cell cycles. EMBO Rep. 2: 1125–1132.[CrossRef][Medline]

Hurlin P.J., Foley K.P., Ayer D.E., Eisenman R.N., Hanahan D., Arbeit J.M. 1995. Regulation of Myc and Mad during epidermal differentiation and HPV-associated tumorigenesis. Oncogene 11: 2487–2501.[Medline]

Indra A.K., Warot X., Brocard J., Bornert J.M., Xiao J.H., Chambon P., Metzger D. 1999. Temporally-controlled site-specific mutagenesis in the basal layer of the epidermis: Comparison of the recombinase activity of the tamoxifen-inducible Cre-ER(T) and Cre-ER(T2) recombinases. Nucleic Acids Res. 27: 4324–4327.[Abstract/Free Full Text]

Kauffmann-Zeh A., Rodriguez-Viciana P., Ulrich E., Gilbert C., Coffer P., Downward J., Evan G. 1997. Suppression of c-Myc-induced apoptosis by Ras signalling through PI(3)K and PKB. Nature 385: 544–548.[CrossRef][Medline]

Kemp C.J. 2005. Multistep skin cancer in mice as a model to study the evolution of cancer cells. Semin. Cancer Biol. 15: 460–473.[CrossRef][Medline]

Kennard M.D., Kang D.C., Montgomery R.L., Butler A.P. 1995. Expression of epidermal ornithine decarboxylase and nuclear proto-oncogenes in phorbol ester tumor promotion-sensitive and -resistant mice. Mol. Carcinog. 12: 14–22.[Medline]

Land H., Parada L.F., Weinberg R.A. 1983. Tumorigenic conversion of primary embryo fibroblasts requires at least two cooperating oncogenes. Nature 304: 596–602.[CrossRef][Medline]

Miliani de Marval P.L., Macias E., Rounbehler R., Sicinski P., Kiyokawa H., Johnson D.G., Conti C.J., Rodriguez-Puebla M.L. 2004. Lack of cyclin-dependent kinase 4 inhibits c-myc tumorigenic activities in epithelial tissues. Mol. Cell. Biol. 24: 7538–7547.[Abstract/Free Full Text]

Missero C., Di Cunto F., Kiyokawa H., Koff A., Dotto G.P. 1996. The absence of p21Cip1/WAF1 alters keratinocyte growth and differentiation and promotes ras-tumor progression. Genes & Dev. 10: 3065–3075.[Abstract/Free Full Text]

Murphy M.J., Wilson A., Trumpp A. 2005. More than just proliferation: Myc function in stem cells. Trends Cell Biol. 15: 128–137.[CrossRef][Medline]

Pelengaris S., Littlewood T., Khan M., Elia G., Evan G. 1999. Reversible activation of c-Myc in skin: Induction of a complex neoplastic phenotype by a single oncogenic lesion. Mol. Cell 3: 565–577.[CrossRef][Medline]

Perez-Losada J. and Balmain A. 2003. Stem-cell hierarchy in skin cancer. Nat. Rev. Cancer 3: 434–443.[CrossRef][Medline]

Prathapam T., Tegen S., Oskarsson T., Trumpp A., Martin G.S. 2006. Activated Src abrogates the Myc requirement for the G0/G1 transition but not for the G1/S transition. Proc. Natl. Acad. Sci. 103: 2695–2700.[Abstract/Free Full Text]

Pruitt K. and Der C.J. 2001. Ras and Rho regulation of the cell cycle and oncogenesis. Cancer Lett. 171: 1–10.[CrossRef][Medline]

Quintanilla M., Brown K., Ramsden M., Balmain A. 1986. Carcinogen-specific mutation and amplification of Ha-ras during mouse skin carcinogenesis. Nature 322: 78–80.[Medline]

Rodriguez-Puebla M.L., Miliani de Marval P.L., LaCava M., Moons D.S., Kiyokawa H., Conti C.J. 2002. Cdk4 deficiency inhibits skin tumor development but does not affect normal keratinocyte proliferation. Am. J. Pathol. 161: 405–411.[Abstract/Free Full Text]

Rounbehler R.J., Schneider-Broussard R., Conti C.J., Johnson D.G. 2001. Myc lacks E2F1’s ability to suppress skin carcinogenesis. Oncogene 20: 5341–5349.[CrossRef][Medline]

Sayama K., Shirakata Y., Midorikawa K., Hanakawa Y., Hashimoto K. 1999. Possible involvement of p21 but not of p16 or p53 in keratinocyte senescence. J. Cell. Physiol. 179: 40–44.[CrossRef][Medline]

Sears R.C. 2004. The life cycle of C-myc: From synthesis to degradation. Cell Cycle 3: 1133–1137.[Medline]

Seoane J., Le H.V., Massague J. 2002. Myc suppression of the p21(Cip1) Cdk inhibitor influences the outcome of the p53 response to DNA damage. Nature 419: 729–734.[CrossRef][Medline]

Serrano M., Lin A.W., McCurrach M.E., Beach D., Lowe S.W. 1997. Oncogenic ras provokes premature cell senescence associated with accumulation of p53 and p16INK4a. Cell 88: 593–602.[CrossRef][Medline]

Topley G.I., Okuyama R., Gonzales J.G., Conti C., Dotto G.P. 1999. p21(WAF1/Cip1) functions as a suppressor of malignant skin tumor formation and a determinant of keratinocyte stem-cell potential. Proc. Natl. Acad. Sci. 96: 9089–9094.[Abstract/Free Full Text]

Trumpp A., Refaeli Y., Oskarsson T., Gasser S., Murphy M., Martin G.R., Bishop J.M. 2001. c-Myc regulates mammalian body size by controlling cell number but not cell size. Nature 414: 768–773.[CrossRef][Medline]

Vaque J.P., Navascues J., Shiio Y., Laiho M., Ajenjo N., Mauleon I., Matallanas D., Crespo P., Leon J. 2005. Myc antagonizes Ras-mediated growth arrest in leukemia cells through the inhibition of the Ras-ERK-p21Cip1 pathway. J. Biol. Chem. 280: 1112–1122.[Abstract/Free Full Text]

Waikel R.L., Kawachi Y., Waikel P.A., Wang X.J., Roop D.R. 2001. Deregulated expression of c-Myc depletes epidermal stem cells. Nat. Genet. 28: 165–168.[CrossRef][Medline]

Watnick R.S., Cheng Y.N., Rangarajan A., Ince T.A., Weinberg R.A. 2003. Ras modulates Myc activity to repress thrombospondin-1 expression and increase tumor angiogenesis. Cancer Cell 3: 219–231.[CrossRef][Medline]

Weinberg W.C. and Denning M.F. 2002. P21Waf1 control of epithelial cell cycle and cell fate. Crit. Rev. Oral Biol. Med. 13: 453–464.[Abstract/Free Full Text]

Wilson A. and Trumpp A. 2006. Bone-marrow haematopoietic-stem-cell niches. Nat. Rev. Immunol. 6: 93–106.[CrossRef][Medline]

Wilson A., Murphy M.J., Oskarsson T., Kaloulis K., Bettess M.D., Oser G.M., Pasche A.C., Knabenhans C., Macdonald H.R., Trumpp A. 2004. c-Myc controls the balance between hematopoietic stem cell self-renewal and differentiation. Genes & Dev. 18: 2747–2763.[Abstract/Free Full Text]

Zanet J., Pibre S., Jacquet C., Ramirez A., de Alboran I.M., Gandarillas A. 2005. Endogenous Myc controls mammalian epidermal cell size, hyperproliferation, endoreplication and stem cell amplification. J. Cell Sci. 118: 1693–1704.[Abstract/Free Full Text]

Zhu S., Yoon K., Sterneck E., Johnson P.F., Smart R.C. 2002. CCAAT/enhancer binding protein- is a mediator of keratinocyte survival and skin tumorigenesis involving oncogenic Ras signaling. Proc. Natl. Acad. Sci. 99: 207–212.[Abstract/Free Full Text]

CiteULike    Connotea    Del.icio.us    Digg    Reddit    Technorati    What's this?

This article has been cited by other articles:

				C. He, H. Hu, R. Braren, S.-Y. Fong, A. Trumpp, T. R. Carlson, and R. A. Wang c-myc in the hematopoietic lineage is crucial for its angiogenic function in the mouse embryo Development, July 15, 2008; 135(14): 2467 - 2477. [Abstract] [Full Text] [PDF]

				N. C. Dubois, C. Adolphe, A. Ehninger, R. A. Wang, E. J. Robertson, and A. Trumpp Placental rescue reveals a sole requirement for c-Myc in embryonic erythroblast survival and hematopoietic stem cell function Development, July 15, 2008; 135(14): 2455 - 2465. [Abstract] [Full Text] [PDF]

				J. A. Wilkins and O. J. Sansom C-Myc Is a Critical Mediator of the Phenotypes of Apc Loss in the Intestine Cancer Res., July 1, 2008; 68(13): 4963 - 4966. [Abstract] [Full Text] [PDF]

				D. Yao, C. L. Alexander, J. A. Quinn, W.-C. Chan, H. Wu, and D. A. Greenhalgh Fos cooperation with PTEN loss elicits keratoacanthoma not carcinoma, owing to p53/p21WAF-induced differentiation triggered by GSK3{beta} inactivation and reduced AKT activity J. Cell Sci., May 15, 2008; 121(10): 1758 - 1769. [Abstract] [Full Text] [PDF]

				E. Fuchs and V. Horsley More than one way to skin . . . Genes & Dev., April 15, 2008; 22(8): 976 - 985. [Abstract] [Full Text] [PDF]

				N. Ohtani, Y. Imamura, K. Yamakoshi, F. Hirota, R. Nakayama, Y. Kubo, N. Ishimaru, A. Takahashi, A. Hirao, T. Shimizu, et al. Visualizing the dynamics of p21Waf1/Cip1 cyclin-dependent kinase inhibitor expression in living animals PNAS, September 18, 2007; 104(38): 15034 - 15039. [Abstract] [Full Text] [PDF]

				C.-H. Wu, J. van Riggelen, A. Yetil, A. C. Fan, P. Bachireddy, and D. W. Felsher Cellular senescence is an important mechanism of tumor regression upon c-Myc inactivation PNAS, August 7, 2007; 104(32): 13028 - 13033. [Abstract] [Full Text] [PDF]

This Article Abstract Full Text (PDF) Supplemental Research Data Alert me when this article is cited Alert me if a correction is posted Citation Map Services Email this article to a friend Similar articles in this journal Similar articles in PubMed Alert me to new issues of the journal Download to citation manager Citing Articles Citing Articles via HighWire Citing Articles via Google Scholar Google Scholar Articles by Oskarsson, T. Articles by Trumpp, A. Search for Related Content PubMed PubMed Citation Articles by Oskarsson, T. Articles by Trumpp, A. Social Bookmarking                   What's this?