Nullifying the CDKN2AB locus promotes mutant K-ras lung tumorigenesis.

UNLABELLED: Lung cancer commonly displays a number of recurrent genetic abnormalities, and about 30% of lung adenocarcinomas carry activating mutations in the Kras gene, often concomitantly with inactivation of tumor suppressor genes p16(INK4A) and p14(ARF) of the CDKN2AB locus. However, little is known regarding the function of p15INK4B translated from the same locus. To determine the frequency of CDKN2AB loss in human mutant KRAS lung cancer, The Cancer Genome Atlas (TCGA) database was interrogated. Two-hit inactivation of CDKN2A and CDKN2B occurs frequently in patients with mutant KRAS lung adenocarcinoma. Moreover, p15INK4B loss occurs in the presence of biallelic inactivation of p16(INK4A) and p14(ARF), suggesting that p15INK4B loss confers a selective advantage to mutant KRAS lung cancers that are p16(INK4A) and p14(ARF) deficient. To determine the significance of CDKN2AB loss in vivo, genetically engineered lung cancer mouse models that express mutant Kras in the respiratory epithelium were utilized. Importantly, complete loss of CDKN2AB strikingly accelerated mutant Kras-driven lung tumorigenesis, leading to loss of differentiation, increased metastatic disease, and decreased overall survival. Primary mutant Kras lung epithelial cells lacking Cdkn2ab had increased clonogenic potential. Furthermore, comparative analysis of mutant Kras;Cdkn2a null with Kras;Cdkn2ab null mice and experiments with mutant KRAS;CDKN2AB-deficient human lung cancer cells indicated that p15INK4B is a critical tumor suppressor. Thus, the loss of CDKN2AB is of biologic significance in mutant KRAS lung tumorigenesis by fostering cellular proliferation, cancer cell differentiation, and metastatic behavior. IMPLICATIONS: These findings indicate that mutant Kras;Cdkn2ab null mice provide a platform for accurately modeling aggressive lung adenocarcinoma and testing therapeutic modalities.

Aldehyde dehydrogenase activity selects for lung adenocarcinoma stem cells dependent on notch signaling.

Aldehyde dehydrogenase (ALDH) is a candidate marker for lung cancer cells with stem cell-like properties. Immunohistochemical staining of a large panel of primary non-small cell lung cancer (NSCLC) samples for ALDH1A1, ALDH3A1, and CD133 revealed a significant correlation between ALDH1A1 (but not ALDH3A1 or CD133) expression and poor prognosis in patients including those with stage I and N0 disease. Flow cytometric analysis of a panel of lung cancer cell lines and patient tumors revealed that most NSCLCs contain a subpopulation of cells with elevated ALDH activity, and that this activity is associated with ALDH1A1 expression. Isolated ALDH(+) lung cancer cells were observed to be highly tumorigenic and clonogenic as well as capable of self-renewal compared with their ALDH(-) counterparts. Expression analysis of sorted cells revealed elevated Notch pathway transcript expression in ALDH(+) cells. Suppression of the Notch pathway by treatment with either a γ-secretase inhibitor or stable expression of shRNA against NOTCH3 resulted in a significant decrease in ALDH(+) lung cancer cells, commensurate with a reduction in tumor cell proliferation and clonogenicity. Taken together, these findings indicate that ALDH selects for a subpopulation of self-renewing NSCLC stem-like cells with increased tumorigenic potential, that NSCLCs harboring tumor cells with ALDH1A1 expression have inferior prognosis, and that ALDH1A1 and CD133 identify different tumor subpopulations. Therapeutic targeting of the Notch pathway reduces this ALDH(+) component, implicating Notch signaling in lung cancer stem cell maintenance.

Dual phosphoinositide 3-kinase/mammalian target of rapamycin blockade is an effective radiosensitizing strategy for the treatment of non-small cell lung cancer harboring K-RAS mutations.

Non-small cell lung cancer (NSCLC) is a leading cause of cancer-related death worldwide. NSCLC often harbors oncogenic K-RAS mutations that lead to the aberrant activation of several intracellular networks including the phosphoinositide 3-kinase (PI3K)/AKT/mammalian target of rapamycin (mTOR) signaling pathway. Oncogenic K-RAS predicts poor prognosis and resistance to treatment with ionizing radiation (IR). Oncogenic K-Ras expression in the respiratory epithelium is sufficient to initiate NSCLC tumorigenesis, which requires the catalytic subunit of PI3K. Thus, effective inhibition of the PI3K signaling should lead to significant antitumor effects. However, therapy with rapamycin analogues has yielded disappointing results due in part to compensatory up-regulation of AKT. We hypothesized that dual PI3K/mTOR blockade would overcome these limitations. We tested this hypothesis with BEZ235, a novel dual PI3K/mTOR inhibitor that has recently entered clinical development. We found that BEZ235 induces a striking antiproliferative effect both in transgenic mice with oncogenic K-RAS-induced NSCLC and in NSCLC cell lines expressing oncogenic K-RAS. We determined that treatment with BEZ235 was not sufficient to induce apoptosis. However, we found that dual PI3K/mTOR blockade effectively sensitizes NSCLC expressing oncogenic K-RAS to the proapoptotic effects of IR both in vitro and in vivo. We conclude that dual PI3K/mTOR blockade in combination with IR may benefit patients with NSCLC expressing oncogenic K-RAS. These findings may have general applicability in cancer therapy, because aberrant activation of PI3K occurs frequently in human cancer.

Activation of the p38 Map kinase pathway is essential for the antileukemic effects of dasatinib.

Dasatinib, a dual Src/Abl tyrosine kinase inhibitor, has significant antileukemic effects against various imatinib mesylate-resistant BCR/ABL mutants. Despite well-documented inhibitory effects of dasatinib on BCR/ABL kinase, the exact downstream cellular events leading to generation of its potent antileukemic effects remain to be defined. We provide evidence that p38 Map kinase (MAPK) pathway is activated leading to increased upregulation of mixed lineage kinase 3, MKK3/6, MSK1, and Mapkapk2, upon treatment of BCR/ABL expressing cells with dasatinib, including cells expressing various imatinib-resistant mutants, except for T315I. Our data demonstrate that such dasatinib-dependent activation of p38 MAPK and its effectors plays a critical role in the generation of antileukemic responses, since pharmacological inhibition of p38 or siRNA-mediated knockdown of its expression reverse dasatinib-mediated apoptosis, cell cycle arrest, and anti-proliferative effects. p38 MAPK inhibition also reversed dasatinib-induced suppression of CML patient-derived leukemic colony-forming units progenitor growth in vitro, as well as BCR/ABL expressing KT-1 cell-derived leukemic progenitor growth. Altogether, our findings suggest a critical role for p38 MAPK pathway in the generation of antileukemic effects of dasatinib, and raise the possibility that development of novel means to enhance p38 MAPK activation in BCR/ABL expressing cells may be an approach to promote antileukemic responses and, possibly, reverse T315I mutation-mediated resistance.

The MDM2-a splice variant of MDM2 alters transformation in vitro and the tumor spectrum in both Arf- and p53-null models of tumorigenesis.

MDM2-A is a common splice variant of murine double minute 2 (MDM2) that is frequently detected in many tumor types. Our previous work has characterized MDM2-A as an activator of p53, and therefore, in a wild-type p53 background, this splice variant would be predicted to confer p53-dependent tumor protection. To test this hypothesis, we used Mdm2-a transgenic mice to assess transformation and tumorigenesis in tumor susceptible murine models. A MDM2-A-dependent decrease in transformation was observed in Arf-null mouse embryonic fibroblasts (MEF) or when wild-type MEFs were exposed to the carcinogen ethylnitrosourea. However, this reduced transformation did not confer tumor protection in vivo; Mdm2-a/Arf-null mice and ethylnitrosourea-treated MDM2-expressing mice developed similar tumor types with equivalent latency compared with their respective controls. Interestingly, when p53 was deleted, MDM2-A expression enhanced transformation of p53-null MEFs and altered tumor spectrum in vivo. In addition, p53-heterozygous mice that expressed MDM2-A developed aggressive mammary tumors that were not observed in p53-heterozygous controls. In conclusion, we found that although MDM2-A expression enhances p53 activity and decreases transformation in vitro, it cannot confer tumor protection. In contrast, MDM2-A seems to exhibit a novel transforming potential in cells where p53 function is compromised. These data show that MDM2 splice variants, such as MDM2-A, may provide protection against transformation of normal tissues having intact p53. However, when such splice variants are expressed in tumors that have defects in the p53 pathway, these isoforms may contribute to tumor progression, which could explain why their expression is often associated with aggressive tumor types.

MDM2-A, a common Mdm2 splice variant, causes perinatal lethality, reduced longevity and enhanced senescence.

MDM2 is the predominant negative regulator of p53 that functions to maintain the appropriate level of expression and activity of this central tumor suppressor. Mdm2-a is a commonly identified splice variant of Mdm2; however, its physiological function is unclear. To gain insight into the activity of MDM2-A and its potential impact on p53, an Mdm2-a transgenic mouse model was generated. Mdm2-a transgenic mice displayed a homozygous-lethal phenotype that could be rescued by a reduction in p53 expression, demonstrating a dependence upon p53. Mdm2-a hemizygous mice exhibited reduced longevity, and enhanced senescence was observed in their salivary glands. In addition, the transgenic mice lacked typical, accelerated aging phenotypes. Growth of transgenic mouse embryonic fibroblasts (MEFs) was inhibited relative to wild-type MEFs, and MDM2-A was shown to bind to full-length MDM2 in an interaction that could increase p53 activity via reduced MDM2 inhibition. Evidence of p53 activation was shown in the Mdm2-a transgenic MEFs, including p53-dependent growth inhibition and elevated expression of the p53 target protein p21. In addition, MDM2-A increased senescence in a p21-independent manner. In conclusion, unexpected roles for MDM2-A in longevity and senescence were identified in a transgenic mouse model, suggesting that Mdm2 splice variants might be determinants of these phenotypes in vivo.

MDM2 splice variants predominantly localize to the nucleoplasm mediated by a COOH-terminal nuclear localization signal.

Of the >40 alternative and aberrant splice variants of MDM2 that have been described to date, the majority has lost both the well-characterized nuclear localization signal (NLS1) and the nuclear export signal (NES) sequence. Because cellular localization of proteins provides insight regarding their potential function, we determined the localization of three different MDM2 splice variants. The splice variants chosen were the common variants MDM2-A and MDM2-B. In addition, MDM2-FB26 was chosen because it is one of the few variants described that contains the complete p53-binding site. All three splice variants predominantly localized to the nucleus. Nuclear localization of MDM2-A and MDM2-B was controlled by a previously uncharacterized nuclear localization signal (NLS2), whereas nucleoplasmic localization of MDM2-FB26 was mediated by NLS1. p53 and full-length MDM2 colocalized with the splice variants in the nucleus. MDM2-A and MDM2-B both contain a COOH-terminal RING finger domain, and interaction with full-length MDM2 through this domain was confirmed. MDM2-FB26 was the only splice variant evaluated that contained a p53-binding domain; however, interaction between MDM2-FB26 and p53 could not be shown. p14(ARF) did not colocalize with the splice variants and was predominantly expressed within the nucleoli. In summary, nuclear localization signals responsible for the nucleoplasmic distribution of MDM2 splice variants have been characterized. Colocalization and interaction of MDM2-A and MDM2-B with full-length MDM2 in the nucleus have important physiologic consequences, for example, deregulation of p53 activity.

Selection for mutations in the cDNAs of transgenic mice upon expression of an embryonic lethal protein.

The generation of transgenic mouse models to study in vivo functions of specific proteins has become common practice. In addition, PCR technology allows efficient and rapid identification of founder mice by the analysis of tail tip DNA. Whilst the DNA construct used in the microinjection of one-cell-stage embryos is usually sequenced it is not common practice to sequence the PCR product once the transgene has been inserted into the mouse genome. In this report we describe why sequencing of inserted transgenes is important. Upon generation of transgenic mice expressing a splice variant of MDM2, MDM2-A, three of four founders contained mutations within the Mdm2-a cDNA sequence. The observation that selection against expression of wild-type MDM2-A resulted in the generation of mice expressing mutant transgenes highlights the importance of sequencing the transgenes of founder mice.

Differential cooperation of oncogenes with p53 and Bax to induce apoptosis in rhabdomyosarcoma.

BACKGROUND: Deregulated expression of oncogenes such as MYC and PAX3-FKHR often occurs in rhabdomyosarcomas. MYC can enhance cell proliferation and apoptosis under specific conditions, whereas PAX3-FKHR has only been described as anti-apoptotic. RESULTS: In order to evaluate how MYC and PAX3-FKHR oncogenes influenced p53-mediated apoptosis, rhabdomyosarcoma cells were developed to independently express MYC and PAX3-FKHR cDNAs. Exogenous wild-type p53 expression in MYC transfected cells resulted in apoptosis, whereas there was only a slight effect in those transfected with PAX3-FKHR. Both oncoproteins induced BAX, but BAX induction alone without expression of wild-type p53 was insufficient to induce apoptosis. Data generated from genetically modified MEFs suggested that expression of all three proteins; MYC, BAX and p53, was required for maximal cell death to occur. CONCLUSION: We conclude that cooperation between p53 and oncoproteins to induce apoptosis is dependent upon the specific oncoprotein expressed and that oncogene-mediated induction of BAX is necessary but insufficient to enhance p53-mediated apoptosis. These data demonstrate a novel relationship between MYC and p53-dependent apoptosis, independent of the ability of MYC to induce p53 that may be important in transformed cells other than rhabdomyosarcoma.

Comparative evaluation of microsatellite marker, AP-PCR and CGH studies in primary renal cell carcinoma.

Renal cancer consists of a heterogeneous tumor group which is characterized by complex cytogenetic and molecular genetic abnormalities. In this study, three different techniques were applied to screen renal cancers for genetic alterations. We studied 99 primary, sporadic renal cancers (96 renal cell carcinomas and three other renal cancers) by a comparative evaluation of different microsatellite markers, comparative genomic hybridization (CGH) and AP-PCR. The AP-PCR produces a genomic fingerprint after an AluEI DNA restriction digest of tumor DNA samples. Microsatellite alterations were investigated using nine microsatellite markers spanning well-known regions of FhiT and VHL (3p14.2, 3p26) but also of oncogenes and tumor suppressor genes like Myc-L1 and TP53Alu (1p32, 17p13.1). To receive a genomic fingerprint, AP-PCR was carried out for all patient samples. Performing AP-PCR, only one case out of 99 displayed genomic imbalance. Seven of 99 investigated primary renal cancers showed alterations in up to four microsatellite loci (TP53Alu, Myc-L1, D3S1300, D3S1560, D3S1317, D3S4260). Three markers (Bat25, Bat26, REN) did not reveal any aberrations within the tested tumor samples. Six cases with microsatellite alterations and four without were examined by CGH. Five samples yielded aberrations, four of them were positive for microsatellite alterations. Only one tumor sample displayed microsatellite alterations, shift patterns in AP-PCR and alterations analyzed by CGH. Our data suggest that genomic aberrations found by microsatellite analysis are also detectable by CGH with the restriction of a minimum of alterated DNA of >10 Mb. Based on this study of RCC and in contrast to other reports for solid tumors, we conclude that AP-PCR is far less informative in investigation of renal cancers.

Loss of heterozygosity at 12q14-15 often occurs in stage I soft tissue sarcomas and is associated with MDM2 amplification in tumors at various stages.

Few studies have investigated the loss of heterozygosity and microsatellite instability in soft tissue sarcomas. Therefore, we analyzed samples of human soft tissue sarcomas to determine the status of the chromosomal region 12q14-15, which contains the MDM2 gene encoding the well-known counterpart of the tumor suppressor p53. In addition, we determined whether an amplified MDM2 gene was present in the samples. Of the 88 soft tissue sarcoma samples, 24 (27%) showed evidence of loss of heterozygosity of markers representing 12q14-15, and 12 (14%) showed evidence of microsatellite instability. Of the 72 samples analyzed by semiquantitative polymerase chain reaction, 15 (21%) possessed an amplified MDM2 gene. Loss of heterozygosity (P =.008) and microsatellite instability (P =.035) were significantly more common in Stage I tumors than in higher stage tumors. This result indicated that these alterations occur early in soft tissue sarcoma progression and possibly define a subgroup of soft tissue sarcoma. Surprisingly, MDM2 amplification in soft tissue sarcoma patients was associated with a prognosis better than that of patients without the amplification; however, this difference was not statistically significant (P =.6). Furthermore, of the tumors with an MDM2 amplification, 40% (6/15) also experienced loss of heterozygosity at 12q14-15; in contrast, only 16% of tumors without an MDM2 amplification (9/57) underwent a loss of heterozygosity. A concomitant occurrence of deletions and amplifications resulting from deficiencies in the nonhomologous end-joining pathway could in part explain this finding.

A novel L-neopentylglycine derivative as auxiliary for copper-catalyzed asymmetric Michael reactions.

L-Neopentylglycine diethylamide (4a). was prepared from the new unnatural amino acid L-neopentylglycine (1). The utilization of amide 4a as a chiral auxiliary in the copper(II)-catalyzed asymmetric Michael reaction was investigated in comparison with L-valine diethylamide (4b). Cyclic beta-oxocarboxylates 7 react with 4a and 4b to give the respective enaminoesters 8, which were converted with methyl vinyl ketone (9) in the presence of 10 mol% Cu(OAc)(2). H2O at room temperature in acetone to yield the optically active Michael addition products (R)-10a, b with high selectivity independent of the starting enamine. In the case of the seven-membered beta-oxocarboxylate 7c, however, the valine-derived enamine 8f led to higher enantioselectivity for product 10c. Despite the bulkiness of the neopentyl group, the isopropyl group with an alpha-branch has a better stereoinducing effect.

Reduced expression of hMSH2 protein is correlated to poor survival for soft tissue sarcoma patients.

BACKGROUND: Deregulation of DNA mismatch repair is a common mechanism for the development of hereditary nonpolyposis colon carcinoma and related familiar cancers, but it also plays a role in the tumorigenesis of sporadic cancers. Although the protein expression of the two main components of DNA mismatch repair, hMSH2 and hMLH1, has been described in soft tissue sarcoma (STS) patients, its prognostic impact is yet to be determined. METHODS: The authors investigated the expression of the DNA repair proteins hMSH2 and hMLH1 by Western blot analysis in tumor samples of 57 STS patients. The correlation between the expression of hMSH2/hMLH1 and survival was studied in a Cox proportional hazards regression model, which was adjusted for the prognostic effects of staging, tumor entity, and radicality of tumor resection. RESULTS: Nine of 57 STS (16%) showed reduced expression of hMSH2 and reduced expression of hMLH1 was detected in seven STS patients (12%). In a Kaplan-Meier analysis, the median survival for patients with reduced expression of the hMSH2 protein was 18 months, whereas the patients with a normal expression of hMSH2 survived for an average of 68 months. A multivariate Cox proportional hazards regression model revealed a significant correlation between the reduced expression of the hMSH2 protein and poor survival (relative risk = 4.7; 95% confidence interval [CI]: 1.3-17.2; P = 0.019). CONCLUSIONS: Reduced expression of the hMSH2 protein is an independent negative prognostic factor for STS patients.