Only a subset of 12-O-tetradecanoylphorbol-13-acetate-promoted mouse skin papillomas are promotable by benzoyl peroxide

The two-stage skin carcinogenesis model of initiation and promotion in Carcinogenesis-susceptible (Car-S) mice has been used to investigate the pathways of promotional activity of 12-O-tetradecanoylphorbol-13-acetate (TPA), a phorbol ester tumor promoter, and benzoyl peroxide (BzPo), a free radical-generating compound. To test whether distinct populations of 9,10-dimethyl-1,2-benzanthracene (DMBA)-initiated epidermal keratinocytes are responsive to the two promoters, tandem experiments were performed. DMBA-initiated Car-S mice were promoted twice weekly with maximal promoting doses of TPA or BzPo. When the number of papillomas/mouse reached a plateau, promotion in the TPA and BzPo groups was switched to BzPo or TPA, respectively, until achievement of a new plateau. Mice promoted with BzPo developed 11.0 +/- 1.3 papillomas/mouse and subsequent TPA promotion induced 13.8 additional papillomas, for a total of 24.8 +/- 2.1 papillomas/mouse. TPA-promoted mice developed 23.3 +/- 1.1 papillomas/mouse, and subsequent BzPo promotion for 91 days did not promote additional papillomas. Our results show a less than additive tumor response after sequential promotion with BzPo and TPA, or vice versa, indicating that the pathways of promotional activity of TPA and BzPo are interacting. While the final papilloma yield was similar at the end of the two tandem promotion experiments independently of promoter sequence, the percentage of mice developing carcinomas was significantly higher in mice that were promoted with BzPo in the first stage. No significant differences in the frequency and type of c-Ha-ras mutations were observed in TPA- and BzPo-promoted tumors, suggesting that promotion of DMBA-initiated cells by BzPo requires introduction of additional molecular alterations compared to TPA.     

Induction of invasive mouse skin carcinomas in transgenic mice with mutations in both H-ras and p53

Synergistic interaction between H-ras and p53 were systematically examined during skin tumorigenesis. Concurrent expression of an activated H-ras gene and a mutant p53 gene was accomplished by crossing p53(Val135/wt) mice with TG.AC mice. Topical application to wild-type mice with benzo(a)pyrene (BaP) alone produced approximately 26% skin tumor incidence, whereas BaP treatment of p53(wt/wt)Hras(TG.AC/wt), p53(Val135/wt)Hras(wt/wt), and p53(Val135/wt)Hras(TG.AC/wt) mice produced a 75%, 77%, and 100% incidence of skin tumors, respectively. An average of 0.33 tumor per mouse was observed in wild-type (p53(wt/wt)Hras(wt/wt)) mice, whereas approximately 1.54, 1.96, and 3.08 tumors per mouse were seen in BaP-treated p53(wt/wt)Hras(TG.AC/wt), p53(Val135/wt)Hras(wt/wt), and p53(Val135/wt)Hras(TG.AC/wt) mice, respectively. The effects on total tumor volume were even more striking with 7-, 48-, and 588-fold increases in tumor volume compared with wild-type (p53(wt/wt)Hras(wt/wt)) in p53(wt/wt)Hras(TG.AC/wt), p53(Val135/wt)Hras(wt/wt), and p53(Val135/wt)Hras(TG.AC/wt) mice, respectively. Histopathologically, all tumors from p53(wt/wt)Hras(wt/wt) mice were either papillomas or well-differentiated squamous cell carcinomas, whereas the tumors in p53(wt/wt)Hras(TG.AC/wt), p53(Val135/wt)Hras(wt/wt), and p53(Val135/wt)Hras(TG.AC/wt) mice were principally squamous cell carcinomas with varying degree of invasiveness. Particularly, tumors in p53(Val135/wt)Hras(TG.AC/wt) mice exhibited the most rapid growth and the extreme form of tumor invasion. Microarray analysis revealed that dominant-negative p53 (Val135) and activated H-ras affected several cellular processes involved in tumorigenesis possibly through its effects on apoptosis, cell cycle arrest, and Ras-mitogen-activated protein kinase pathways. The present study provides the first in vivo evidence that a germ line p53 mutation and activated H-ras act synergistically to profoundly enhance tumor progression.     

Linkage disequilibrium and haplotype mapping of a skin cancer susceptibility locus in outbred mice

Car-R (carcinogenesis-resistant) and Car-S (carcinogenesis-susceptible) outbred mice, obtained by phenotypic selection from an initial intercross of eight inbred strains, show a >100-fold difference in their susceptibility to two-stage skin tumorigenesis. We found that the lines carry a high degree of genetic polymorphism, with an average heterozygosity of 0.39. This polymorphism allowed the use of linkage disequilibrium (LD) and haplotype analysis for the mapping of a skin cancer modifier locus on Chr 7, in a short region of 6 cM, around the Tyr gene. Car-S mice inherited the susceptibility allele at this locus from the A/J, BALB/c, SJL/J, and SWR/J strains. Our results demonstrate the feasibility and usefulness of mapping disease genes by LD in phenotypically selected, genetically heterogeneous animals. Received: 16 March 2000 / Accepted: 9 June 2000     

Use of intercross outbred mice and single nucleotide polymorphisms to map skin cancer modifier loci

Car-R and Car-S outbred mouse lines, phenotypically selected for resistance and susceptibility to skin carcinogenesis respectively, show significant linkage disequilibrium (LD) at genetic markers mapping on chromosomal regions where skin cancer modifier loci (Skts3, Skts1, and Psl1 on Chrs 5, 7, and 9 respectively) have been mapped in standard crosses. Analysis of these regions for genetic linkage with skin cancer phenotypes in 245 (Car-R × Car-S)F₂ intercross mice, by using single nucleotide polymorphisms (SNPs), revealed significant linkage at a possible allelic form of the Skts1 locus, whose mapping region was shortened to a <5.5-cM interval near the Tyr locus. The Car-derived Skts1 locus was linked with papilloma multiplicity and latency by a recessive inheritance of the susceptibility allele. Putative loci on Chr 5 (Skts3) and 9 (Psl1) showed no significant linkage. These results point to the important role of the Stks1 locus in mouse skin tumorigenesis in independent crosses. The shortened Skts1 mapping region should facilitate the identification of candidate genes. Received: 23 June 2000 / Accepted: 22 November 2000     

Biological and molecular aspects of radiation carcinogenesis in mouse skin

The process of mouse skin carcinogenesis can be operationally subdivided into at least three stages which have been termed initiation, promotion, and progression. Ionizing radiation has been found to be a weak initiator of malignant squamous cell carcinomas (SCCs) when radiation was followed by repeated treatments of the skin with the tumor promoter 12-O-tetradecanoyl-phorbol-13-acetate (TPA). Besides SCCs, ionizing radiation was found to induce, independent of tumor promoters, basal cell carcinomas (BCCs), a tumor histology not normally seen with chemical carcinogens and mouse skin. Fractionated doses of 1 MeV electrons were found to enhance the conversion of chemically induced benign papillomas to malignant SCCs. In addition to the biological studies, questions related to dominant transforming genes and differential gene expression in the radiation-initiated mouse skin tumors have been explored. Distinct non-ras dominant transforming gene(s) have been detected in radiation-initiated, TPA-promoted SCCs. Differences in the expression pattern of tumor-associated genes were seen in comparing chemically to radiation-induced benign and malignant skin tumors. Therefore, ionizing radiation has been shown to be active in the initiation of malignant skin tumors and progression of benign to malignant tumors in the mouse skin. The ability to divide the process of carcinogenesis into multiple stages in the mouse skin model has facilitated mechanistic studies that may elucidate the molecular pathways involved in radiation-versus chemically induced tumor development.     

p19Arf suppresses growth, progression, and metastasis of Hras-driven carcinomas through p53-dependent and -independent pathways

Ectopic expression of oncogenes such as Ras induces expression of p19(Arf), which, in turn, activates p53 and growth arrest. Here, we used a multistage model of squamous cell carcinoma development to investigate the functional interactions between Ras, p19(Arf), and p53 during tumor progression in the mouse. Skin tumors were induced in wild-type, p19(Arf)-deficient, and p53-deficient mice using the DMBA/TPA two-step protocol. Activating mutations in Hras were detected in all papillomas and carcinomas examined, regardless of genotype. Relative to wild-type mice, the growth rate of papillomas was greater in p19(Arf)-deficient mice, and reduced in p53-deficient mice. Malignant conversion of papillomas to squamous cell carcinomas, as well as metastasis to lymph nodes and lungs, was markedly accelerated in both p19 (Arf)- and p53-deficient mice. Thus, p19(Arf) inhibits the growth rate of tumors in a p53-independent manner. Through its regulation of p53, p19(Arf) also suppresses malignant conversion and metastasis. p53 expression was upregulated in papillomas from wild-type but not p19( Arf)-null mice, and p53 mutations were more frequently seen in wild-type than in p19( Arf)-null carcinomas. This indicates that selection for p53 mutations is a direct result of signaling from the initiating oncogenic lesion, Hras, acting through p19(Arf).     

Transgenic overexpression of transforming growth factor alpha bypasses the need for c-Ha-ras mutations in mouse skin tumorigenesis.

The induction of skin papillomas in mice can be divided into two different stages. Chemical initiation frequently elicits mutations in the Ha-ras gene, leading to the constitutive activation of ras. The second step, promotion, involves repetitive topical application of phorbol esters or wounding, leading to epidermal hyperproliferation and papilloma formation. We have found that overexpression of transforming growth factor alpha (TGF-alpha) in the basal epidermal layer of transgenic mice yielded papillomas directly upon wounding or 12-O-tetradecanoylphorbol-13-acetate treatment without the need for an initiator. Moreover, papillomas from TGF-alpha mice did not exhibit mutations in the Ha-ras gene. Interestingly, TGF-alpha acted synergistically with 12-O-tetradecanoylphorbol-13-acetate to enhance epidermal hyperproliferation. Our results demonstrate a central role for TGF-alpha overexpression in tumorigenesis and provide an important animal model for the study of skin tumorigenesis.     

v-ras genes from Harvey and BALB murine sarcoma viruses can act as initiators of two-stage mouse skin carcinogenesis

Activated Harvey murine sarcoma virus ras genes were introduced into epidermal cells in vivo by direct application of retroviruses to mouse skin. Subsequent treatment with the tumor promoter 12-O-tetradecanoyl-phorbol-13-acetate (TPA) induced benign papillomas, some of which progressed to invasive carcinomas. Initiation with virus was irreversible for at least 4 months, since TPA treatment after this latency period produced papillomas within 4 weeks. Analysis of viral integration sites showed that carcinomas are clonal in origin. Both papillomas and carcinomas express virus-specific ras mRNA and the viral form of ras P21 protein. The results show that activated ras genes can replace chemical carcinogens in initiation of mouse skin carcinogenesis. This system presents a novel approach to in vivo analysis of the biological role of oncogenes in epithelial tumorigenesis.     

Ionizing radiation as an initiator in the mouse two-stage model of skin tumor formation

The initiating potential of a range (7.5 to 22.5 Gy) of 4 MeV X rays was studied using the mouse skin two-stage model of carcinogenesis. A single dose of radiation was followed by 60 weeks of promotion with 12-O-tetradecanoyl phorbol-13-acetate (TPA) (8 nmol, two times per week). Since the proliferative state of a target cell population is known to influence carcinogen-induced tumorigenesis, we also investigated the effect of TPA on tumor incidence when applied as a single dose (17 nmol) 24 h prior to irradiation. Evidence presented here indicates that ionizing radiation can act as an initiator in this model system. All groups of animals that were promoted with TPA developed papillomas regardless of radiation treatment; however, only those groups of animals that received irradiation followed by TPA promotion developed squamous cell carcinomas. The incidence of nonepidermal tumors was similar between all radiation dose groups and was independent of TPA promotion. Our results also indicate that TPA pretreatment prior to irradiation results in an overall increase in the total tumor incidence, including both epidermal and nonepidermal tumors.     

IL-1 alpha,innate immunity,and skin carcinogenesis: the effect of constitutive expression of IL-1 alpha in epidermis on chemical carcinogenesis

Tumor promoters such as the phorbol ester 12-O-tetradecanoylphorbol-13-acetate (TPA) are proinflammatory agents, and their mechanism of action in epithelial carcinogenesis has been linked to the release of IL-1 alpha and the induction of chronic inflammation in skin. To test the role of IL-1 alpha and inflammation in models of cutaneous carcinogenesis, we used our previously described FVB/N transgenic mice overexpressing 17-kDa IL-1 alpha in the epidermis under the keratin 14 (K14) promoter. Strikingly, the K14/IL-1 alpha mice were completely resistant to papilloma and carcinoma formation induced by a two-stage DMBA/TPA protocol, while littermate controls developed both tumor types. K14/IL-1 alpha mice crossed with the highly sensitive TG.AC mice, constitutively expressing mutant Ha-Ras, also failed to develop papillomas or carcinomas. When the K14/IL-1 alpha transgene was bred onto a recombinase-activating gene-2-deficient background, the resistance persisted, indicating that innate, but not acquired, mechanisms may be involved in the resistance to the initiation/promotion model. As an alternative approach, a complete carcinogenesis protocol using repetitive application of DMBA alone was applied. Surprisingly, although the IL-1 alpha mice still did not develop papillomas, they did develop carcinomas de novo at an accelerated rate compared with controls. We conclude that constitutive IL-1 alpha expression rendered FVB mice completely resistant to carcinomas that required evolution from prior papillomas, but facilitated carcinomas that did not evolve from papillomas, as in the complete carcinogenesis protocol. Thus, the role of IL-1 alpha and, by extension that of other proinflammatory factors, in epithelial carcinogenesis are more complex than previously appreciated. These mice may provide a mechanism to investigate the validity of these models of human skin tumorigenesis.     

E2F1 Has Both Oncogenic and Tumor-Suppressive Properties in a Transgenic Model

Using a transgenic mouse model expressing the E2F1 gene under the control of a keratin 5 (K5) promoter, we previously demonstrated that increased E2F1 activity can promote tumorigenesis by cooperating with either a v-Ha-ras transgene to induce benign skin papillomas or p53 deficiency to induce spontaneous skin carcinomas. We now report that as K5 E2F1 transgenic mice age, they are predisposed to develop spontaneous tumors in a variety of K5-expressing tissues, including the skin, vagina, forestomach, and odontogenic epithelium. On the other hand, K5 E2F1 transgenic mice are found to be resistant to skin tumor development following a two-stage carcinogenesis protocol. Additional experiments suggest that this tumor-suppressive effect of E2F1 occurs at the promotion stage and may involve the induction of apoptosis. These findings demonstrate that increased E2F1 activity can either promote or inhibit tumorigenesis, dependent upon the experimental context.     

Mice deficient in tumor necrosis factor-alpha are resistant to skin carcinogenesis.

Given the associations between chronic inflammation and epithelial cancer, we studied susceptibility to skin carcinogenesis in mice deficient for the pro-inflammatory cytokine TNF-alpha (refs. 5,6). TNF-alpha(-/-) mice were resistant to development of benign and malignant skin tumors, whether induced by initiation with DMBA and promotion with TPA or by repeated dosing with DMBA. TNF-alpha(-/-) mice developed 5-10% the number of tumors developed by wild-type mice during initiation/promotion and 25% of those in wild-type mice after repeated carcinogen treatment. TNF-alpha could influence tumor and stromal cells during tumor development. The early stages of TPA promotion are characterized by keratinocyte hyperproliferation and inflammation. These were diminished in TNF-alpha(-/-) mice. TNF-alpha was extensively induced in the epidermis, but not the dermis, in TPA-treated wild-type skin, indicating that dermal inflammation is controlled by keratinocyte TNF-alpha production. Deletion of a TNF-alpha inducible chemokine also conferred some resistance to skin tumor development. TNF-alpha has little influence on later stages of carcinogenesis, as tumors in wild-type and TNF-alpha(-/-) mice had similar rates of malignant progression. These data provide evidence that a pro-inflammatory cytokine is required for de novo carcinogenesis and that TNF-alpha is important to the early stages of tumor promotion. Strategies that neutralize TNF-alpha production may be useful in cancer treatment and prevention.     

Polyamine biosynthesis and skin tumor promotion: inhibition of 12-O-tetradecanoylphorbol-13-acetate-promoted mouse skin tumor formation by the irreversible inhibitor of ornithine decarboxylase alpha-difluoromethylornithine

Application of 12-0-tetradecanoylphorbol-13-acetate (TPA) to mouse skin leads to the induction of ornithine decarboxylase (EC 4.1.1.17) and the accumulation of putrescine. The relevance of these TPA-induced changes to the mechanism of tumor promotion was determined using α-difluoromethylornithine, an irreversible inhibitor of ornithine decarboxylase. α-Difluoromethylornithine applied to the skin of mice or administered in drinking water in conjunction with applications of TPA to 7,12-dimethylbenz[a]anthracene-initiated mouse skin inhibited the formation of mouse skin papillomas by 50 and 90% respectively; TPA-induced ornithine decarboxylase activity and the accumulation of putrescine were almost completely inhibited.     

Beta-radiation-induced resistance to MNNG initiation of papilloma but not carcinoma formation in mouse skin

We have shown previously that the risk of tumor initiation, promotion, and progression in animals initiated with alkylating agents can be drastically altered by hyperthermia treatments. We show here that ionizing radiation can also alter the risk of tumor initiation by alkylating agents. Using a two-step skin tumorigenesis protocol in female SENCAR mice (initiation by MNNG, promotion with TPA), we exposed the dorsal skin of the mice to various doses of 90Sr/90Y beta radiation near the time of initiation. The radiation produced a dose-dependent reduction in the number of papillomas which appeared after TPA promotion, with about a 20% reduction in animals receiving 0.5 Gy surface dose just before initiation, about 50% reduction after 2.5 Gy, and greater than 80% at doses above 5 Gy. A dose of 2.5 Gy in animals initiated with DMBA produced no significant reduction. One skin hyperthermia treatment (44 degrees C, 30 min) along with radiation in MNNG-initiated animals partially blocked the protective effect of radiation and increased the papilloma frequency. Radiation (2.5 Gy) given either 6 days before or after MNNG initiation was less effective but still reduced papilloma frequency about 20%. In sharp contrast to the marked reduction in papilloma formation, these same animals showed no change in carcinoma frequency with any of the doses or schedules of beta radiation. MNNG initiation alone produced three types of initiated cells. One type, produced in low yield, was promotion-independent with a high probability of progression to a carcinoma and appeared unaffected by the radiation. A second type, produced in intermediate yield, was promotion-dependent and also had a high progression probability, but was likewise unaffected by the radiation. The third and most abundant type was promotion-dependent with a very low progression probability. Radiation exposure resulted in a decrease in the risk of an MNNG initiation event which led only to the third type of cell. The data therefore indicate that the risk of some, but not all, tumor-initiating events caused by alkylating agents can be reduced by an exposure to ionizing radiation.     

Isoform-specific ras activation and oncogene dependence during MYC- and Wnt-induced mammary tumorigenesis

We have previously shown that c-MYC-induced mammary tumorigenesis in mice proceeds via a preferred secondary pathway involving spontaneous activating mutations in Kras2 (C. M. D'Cruz, E. J. Gunther, R. B. Boxer, J. L. Hartman, L. Sintasath, S. E. Moody, J. D. Cox, S. I. Ha, G. K. Belka, A. Golant, R. D. Cardiff, and L. A. Chodosh, Nat. Med. 7:235-239, 2001). In contrast, we now demonstrate that Wnt1-induced mammary tumorigenesis proceeds via a pathway that preferentially activates Hras1. In addition, we find that expression of oncogenic forms of Kras2 and Hras1 from their endogenous promoters has markedly different consequences for the progression of tumors to oncogene independence. Spontaneous activating Kras2 mutations occurring in either MYC- or Wnt1-induced tumors were strongly associated with oncogene-independent tumor growth following MYC or Wnt1 downregulation. In contrast, Hras1-mutant Wnt1-induced tumors consistently remained oncogene dependent. Additionally, Kras2-mutant tumors exhibited substantially higher levels of ras-GTP, phospho-Erk1/2, and phospho-Mek1/2 compared to Hras1-mutant tumors, suggesting the involvement of the ras/mitogen-activated protein kinase (MAPK) pathway in the acquisition of oncogene independence. Consistent with this, by use of carcinogen-induced ras mutations as well as knock-in mice harboring a latent activated Kras2 allele, we demonstrate that Kras2 activation strongly synergizes with both c-MYC and Wnt1 in mammary tumorigenesis and promotes the progression of tumors to oncogene independence. Together, our findings support a model for tumorigenesis in which c-MYC and Wnt1 select for the outgrowth of cells harboring mutations in specific ras isoforms and that these secondary mutations, in turn, determine the extent of ras/MAPK pathway activation and the potential for oncogene-independent growth.     

Inhibitory effect of toluene on tumor promotion in mouse skin

In the two-stage mouse model for skin tumorigenesis with phorbol-12-myristate-13-acetate (PMA) as promoter, topical application of 40 microliters of toluene 2X/week at the initiation/promotion site (the back) reduced the average number of tumors/mouse (ANT/M) to approximately one-fourth that of controls. Control procedure involved initiation of C3H mice with benzo[a]pyrene (BaP) and CD-1 mice with 7,12-dimethylbenz[a]anthracene (DMBA) followed by promotion with from 1 to 5 micrograms PMA in 40 microliters acetone 2X/week. Forty microliters of toluene 2X/week per se was a weak promoter (6-13% of control ANT/M), and produced mild skin irritation at the application site but behavior and body weights were normal. The toluene inhibition of tumorigenesis was not a direct chemical action on PMA since similar effects occurred whether toluene was the vehicle for PMA or whether it was applied up to 1 day before PMA (i.e., prepromotion). Prepromotion with acetone had no effect on tumorigenesis, substantiating its use as control vehicle and suggesting that the toluene inhibition was a specific tissue reaction. The inhibitory effect appeared to be on PMA promotion rather than on initiation since toluene and acetone produced similar numbers of tumors when used as the vehicle for BaP or DMBA in two-stage or BaP in single-stage trials. The inhibition was not permanent since tumorigenesis returned to control rates 2-3 weeks after prepromotion with toluene ceased but promotion with PMA in acetone continued. Toluene may be unique among reported promotion inhibitors in that it is a widely used commercial chemical which sometimes serves as a vehicle in cancer-screening trials. Since its metabolism is reasonably well defined, it may be of value in exploring further the process of tumor promotion.     

Altered tumor biology and tumorigenesis in irradiated and chemical carcinogen-treated single and combined connexin32/p27Kip1-deficient mice

Connexin32 knockout mice (Cx32-KO) exhibit increased chemical and radiation-induced liver and lung tumorigenesis. This increased tumor incidence is associated with altered tumor biology including enhanced tumor progression and an increased percent of MAPK-active tumors. Likewise, mice lacking the tumor suppressor/cell cycle regulator p27Kip1 exhibit increased tumorigenesis in a variety of tissues following chemical and radiation induction. Interestingly, in a double-deficient mouse model (DKO), additional loss of p27Kip1 in a Cx32-KO background results in attenuation of liver and lung tumorigenesis as well as MAPK activation profiles, suggesting pathway interaction. While these mouse strains exhibit altered liver and lung tumor susceptibility following both chemical (DEN) and radiation (X-ray) induction protocols, comparisons of the resulting tumor incidence, multiplicity, tumor progression, and MAPK activation in response to these two distinct carcinogens underscores the separate influence of each individual gene on both tumor formation and activation of specific oncogenic pathways. Furthermore, these studies demonstrate that different carcinogens interact disparately with Cx32/p27Kip1 genotypic backgrounds in situ resulting in varied tumorigenic response.     

12-O-tetradecanoylphorbol-13-acetate and UV radiation-induced nucleoside diphosphate protein kinase B mediates neoplastic transformation of epidermal cells

The molecular changes associated with early skin carcinogenesis are largely unknown. We have previously identified 11 genes whose expression was up- or down-regulated by 12-O-tetradecanoylphorbol-13-acetate (TPA) in mouse skin keratinocyte progenitor cells (Wei, S.-J., Trempus, C. S., Cannon, R. E., Bortner, C. D., and Tennant, R. W. (2003) J. Biol. Chem. 278, 1758-1768). Here, we show an induction of a nucleoside diphosphate protein kinase B (NDPK-B) gene in response to TPA or UV radiation (UVR). TPA or UVR significantly induced the expression of NDPK-B both in vivo hyperplastic mouse skin and in vitro mouse JB6 Cl 41-5a epidermal cells. Indeed, this gene was also up-regulated in TPA or UVR-mediated skin tumors including papillomas, spindle cell tumors, and squamous cell carcinomas, relative to adjacent normal skins. Functional studies by constitutive expression of nm23-M2/NDPK-B in TPA susceptible JB6 Cl 41-5a and TPA-resistant JB6 Cl 30-7b preneoplastic epidermal cell lines showed a remarkable gene dosage-dependent increase in foci-forming activity, as well as an enhancement in the efficiency of neoplastic transformation of these cells in soft agar but no effect on proliferation in monolayer cultures. Interestingly, stable transfection of the nm23-M2/NDPK-B del-RGD or G106A mutant gene in JB6 Cl 41-5a cells selectively abrogated NDPK-B-induced cellular transformation, implicating a possible Arg105-Gly106-Asp107 regulatory role in early skin carcinogenesis.     

Altered Tumor Biology and Tumorigenesis in Irradiated and Chemical Carcinogen-Treated Single and Combined Connexin32/p27Kip1-Deficient Mice

Connexin32 knockout mice (Cx32-KO) exhibit increased chemical and radiation-induced liver and lung tumorigenesis. This increased tumor incidence is associated with altered tumor biology including enhanced tumor progression and an increased percent of MAPK-active tumors. Likewise, mice lacking the tumor suppressor/cell cycle regulator p27^Kip1 exhibit increased tumorigenesis in a variety of tissues following chemical and radiation induction. Interestingly, in a double-deficient mouse model (DKO), additional loss of p27^Kip1 in a Cx32-KO background results in attenuation of liver and lung tumorigenesis as well as MAPK activation profiles, suggesting pathway interaction. While these mouse strains exhibit altered liver and lung tumor susceptibility following both chemical (DEN) and radiation (X-ray) induction protocols, comparisons of the resulting tumor incidence, multiplicity, tumor progression, and MAPK activation in response to these two distinct carcinogens underscores the separate influence of each individual gene on both tumor formation and activation of specific oncogenic pathways. Furthermore, these studies demonstrate that different carcinogens interact disparately with Cx32/p27^Kip1 genotypic backgrounds in situ resulting in varied tumorigenic response.