Hybrids of aneuploid human cancer cells permit complementation of simple and complex cancer defects.

Causes for the complex phenotypes of cancers, such as altered differentiation, invasion and metastasis, are not known, and multigenic defects are likely. In contrast, well-defined deficiencies, such as those affecting DNA-repair mechanisms and enzymatic pathways, are simple, typically caused by one or a few gene mutations. Complementation by introducing defined genetic elements is used to study simple cancer phenotypes, while complementation by the fusion of whole cells is employed occasionally for complex ones. Hybrids formed solely from the common lines (aneuploid due to chromosomal instability, CIN) are rarely reported. We created stable hybrids of two CIN lines, producing a nearly complete genetic sum of the parental karyotypes. Complementation of a simple cancer phenotype, a Fanconi anemia pathway defective in both parental lines, occurred in all hybrids, restoring the normal drug-resistance phenotype. The grossly defective mitotic spindle checkpoint present in both parental lines was partially corrected in some hybrids, supporting a multigenic origin rather than a single gene defect. Using Affymetrix 100K SNP chips, we mapped chromosomal loci differing among the phenotypically distinct hybrid clones. Fusing CIN cell lines to form mapped hybrids offers new tools for positional cloning or classification of simple and complex cancer phenotypes, including mechanical defects and altered drug responses.

Frequent mutations in the 3'-untranslated region of IFNGR1 lack functional impairment in microsatellite-unstable colorectal tumours.

Microsatellite repeats are frequently found to be mutated in microsatellite-instable colorectal tumours. This suggests that these mutations are important events during tumour development. We have observed frequent mutations in microsatellite-instable (MSI-H) tumours and cell lines of a conserved A14 repeat within the 3'-untranslated region of the interferon-gamma receptor 1 gene (IFNGR1). The repeat was mutated in 59% (41 of 70) of colon carcinomas and in all four MSI-H colon cancer cell lines tested. In-vitro analysis of these cell lines did not show a decreased responsiveness to standard IFNgamma concentrations when compared to microsatellite-stable colon cancer cell lines. A functional consequence of the frequently found microsatellite instability in IFNGR1 is therefore not evident.

High-throughput screening identifies novel agents eliciting hypersensitivity in Fanconi pathway-deficient cancer cells.

Inactivation of the Fanconi anemia (FA) pathway occurs in diverse human tumors among the general population and renders those tumors hypersensitive to DNA interstrand-cross-linking (ICL) agents. The identification of novel agents to which FA pathway-deficient cells were hypersensitive could provide new therapeutic opportunities and improve our molecular understanding of the FA genes. Using high-throughput screening, we assessed the growth of isogenic human cancer cells that differed only in the presence or absence of single FA genes upon treatment with 880 active drugs and 40,000 diverse compounds. We identified several compounds to which FA pathway-deficient cells were more sensitive than FA pathway-proficient cells, including two groups of structurally related compounds. We further investigated the compound eliciting the strongest effect, termed 80136342. Its mechanism of action was distinct from that of ICL agents; 80136342 did not cause increased chromosomal aberrations, enhanced FANCD2 monoubiquitination, H2AX phosphorylation, p53 activation, or ICL induction. Similar to ICL agents, however, 80136342 caused a pronounced G(2) arrest in FA pathway-deficient cells. When applied in combination with ICL agents, 80136342 had at least additive toxic effects, excluding interferences on ICL-induced toxicity and facilitating a combinational application. Finally, we identified one particular methyl group necessary for the effects of 80136342 on FA-deficient cells. In conclusion, using high-throughput screening in an isogenic human FA cancer model, we explored a novel approach to identify agents eliciting hypersensitivity in FA pathway-deficient cells. We discovered several attractive candidates to serve as lead compounds for evaluating structure-activity relationships and developing therapeutics selectively targeting FA pathway-deficient tumors.

Targeted deletion of MKK4 in cancer cells: a detrimental phenotype manifests as decreased experimental metastasis and suggests a counterweight to the evolution of tumor-suppressor loss.

Tumor-suppressors have commanded attention due to the selection for their inactivating mutations in human tumors. However, relatively little is understood about the inverse, namely, that tumors do not select for a large proportion of seemingly favorable mutations in tumor-suppressor genes. This could be explained by a detrimental phenotype accruing in a cell type-specific manner to most cells experiencing a biallelic loss. For example, MKK4, a tumor suppressor gene distinguished by a remarkably consistent mutational rate across diverse tumor types and an unusually high rate of loss of heterozygosity, has the surprisingly low rate of genetic inactivation of only approximately 5%. To explore this incongruity, we engineered a somatic gene knockout of MKK4 in human cancer cells. Although the null cells resembled the wild-type cells regarding in vitro viability and proliferation in plastic dishes, there was a marked difference in a more relevant in vivo model of experimental metastasis and tumorigenesis. MKK4(-/-) clones injected i.v. produced fewer lung metastases than syngeneic MKK4-competent cells (P = 0.0034). These findings show how cell type-specific detrimental phenotypes can offer a paradoxical and yet key counterweight to the selective advantage attained by cells as they experiment with genetic null states during tumorigenesis, the resultant balance then determining the observed biallelic mutation rate for a given tumor-suppressor gene.

Identification of a 7.1-mega base pairs minimal deletion at 14q31.1-32.11 in adenocarcinomas of the gastroesophageal junction.

In a recent evaluation by comparative genomic hybridization, we demonstrated chromosome 14q31-32.1 to be frequently deleted in adenocarcinomas of the gastroesophageal junction. This suggests the presence of a tumor suppressor gene in the deleted region. In the present study, we have performed a detailed loss of heterozygosity analysis in 34 gastroesophageal junction adenocarcinomas and 1 tumor-corresponding dysplastic Barrett's epithelium sample with 37 polymorphic microsatellite markers. Thirty-five markers are in the 14q24.3-32.33 region with a mean distance of 800 kilo base pairs. Of 34 tumor samples, 14 (41%) showed loss of 14q markers. We identified a minimal region of allelic loss of 7105440 base pairs between markers D14S1000 and D14S256 at cytogenetic location 14q31.1-32.11. Within this region, markers D14S1035, D14S55, D14S1037, D14S1022, D14S1052, D14S974, D14S73, D14S1033, D14S67, D14S68, and D14S1058 showed loss in all informative tumors with 14q loss. The region between markers D14S1000 and D14S256 contains 7 known genes. The identification of this minimal deletion and the data base information on the genes present in this region facilitate the search for the candidate tumor suppressor gene(s).

Theoretical proposal: allele dosage of MAP2K4/MKK4 could rationalize frequent 17p loss in diverse human cancers.

Although aneuploidy is a global genomic abnormality present in most human cancers, the clonal selection model best explains the action of select activating mutations in oncogenes and homozygous losses of tumor-suppressor genes. Simple gene dosage changes are difficult however, to incorporate into this model, in part due to negative feedback loops that govern major cancer mutational targets (e.g., TP53, PTCH, SMAD4) and essentially preclude a haploinsufficient phenotype. The 17p conundrum may offer a clue to reconciling this difficulty: In comparison to the moderate mutation rate of TP53, many tumors have a disproportionately high frequency of loss of 17p. This discrepancy, and similar discrepancies at other sites of LOH, has long been thought to be due to the presence of undiscovered yet frequently mutated tumor-suppressor genes. However, over 15 years of searching for this grail has distributed bountiful disappointment. It is perhaps time to seriously consider an alternative explanation. Located on 17p adjacent to the TP53 gene, MKK4 is one of the most consistently mutated genes across tumor types, and is located on one of the most frequently lost arms in the human genome. We theorized that a gene dosage-dependent phenotype of MKK4 could plausibly promote the emergence of 17p LOH and thereby the probability of evolving the biallelic inactivation of TP53. Using MKK4 somatic human knockout cancer cells, we observed the proof-of-principle in the downstream gene dosage-dependent phenotypes: heterozygous and homozygous knockouts were progressively deficient in Mkk4 protein, in stress-induced phosphorylation of Jnk, and the resultant upregulation of JUN mRNA. These observations highlight a lack of compensatory regulation when gene dosage changes perturb the Jnk-Jun relationship. Consideration of gene dosage changes specifically affecting members of positive feedback loops may permit integration of the aneuploidy process into a conventional model of clonal selection in tumorigenesis.

In vivo therapeutic responses contingent on Fanconi anemia/BRCA2 status of the tumor.

PURPOSE: BRCA2, FANCC, and FANCG gene mutations are present in a subset of pancreatic cancer. Defects in these genes could lead to hypersensitivity to interstrand cross-linkers in vivo and a more optimal treatment of pancreatic cancer patients based on the genetic profile of the tumor. EXPERIMENTAL DESIGN: Two retrovirally complemented pancreatic cancer cell lines having defects in the Fanconi anemia pathway, PL11 (FANCC-mutated) and Hs766T (FANCG-mutated), as well as several parental pancreatic cancer cell lines with or without mutations in the Fanconi anemia/BRCA2 pathway, were assayed for in vitro and in vivo sensitivities to various chemotherapeutic agents. RESULTS: A distinct dichotomy of drug responses was observed. Fanconi anemia-defective cancer cells were hypersensitive to the cross-linking agents mitomycin C (MMC), cisplatin, chlorambucil, and melphalan but not to 5-fluorouracil, gemcitabine, doxorubicin, etoposide, vinblastine, or paclitaxel. Hypersensitivity to cross-linking agents was confirmed in vivo; FANCC-deficient xenografts of PL11 and BRCA2-deficient xenografts of CAPAN1 regressed on treatment with two different regimens of MMC whereas Fanconi anemia-proficient xenografts did not. The MMC response comprised cell cycle arrest, apoptosis, and necrosis. Xenografts of PL11 also regressed after a single dose of cyclophosphamide whereas xenografts of genetically complemented PL11(FANCC) did not. CONCLUSIONS: MMC or other cross-linking agents as a clinical therapy for pancreatic cancer patients with tumors harboring defects in the Fanconi anemia/BRCA2 pathway should be specifically investigated.

Functional defects in the fanconi anemia pathway in pancreatic cancer cells.

Biallelic BRCA2-mutations can cause Fanconi anemia and are found in approximately 7% of pancreatic cancers. Recently, several sequence changes in FANCC and FANCG were reported in pancreatic cancer. Functional defects in the Fanconi pathway can result in a marked hypersensitivity to interstrand crosslinking agents, such as mitomycin C. The functional implications of mutations in the Fanconi pathway in cancer have not been fully studied yet; these studies are needed to pave the way for clinical trials of treatment with crosslinking agents of Fanconi-defective cancers. The competence of the proximal Fanconi pathway was screened in 21 pancreatic cancer cell lines by an assay of Fancd2 monoubiquitination using a Fancd2 immunoblot. The pancreatic cancer cell lines Hs766T and PL11 were defective in Fancd2 monoubiquitination. In PL11, this defect led to the identification of a large homozygous deletion in FANCC, the first cancer cell line found to be FANCC-null. The Fanconi-defective cell lines Hs766T, PL11, and CAPAN1 were hypersensitive to the crosslinking agent mitomycin C and some to cis-platin, as measured by cell survival assays and G(2)/M cell-cycle arrest. These results support the practical exploration of crosslinking agents for non-Fanconi anemia patients that have tumors defective in the Fanconi pathway.