A transcriptome map of cellular transformation by the fos oncogene

BACKGROUND: The c-fos gene was originally identified as the cellular homolog of the oncogene v-fos carried by the Finkel-Biskis-Jenkins and Finkel-Biskis-Reilly murine osteogenic sarcoma retroviruses. Sustained expression of fos is sufficient to induce cellular transformation in vitro and tumorigenesis in vivo. Fos functions as a component of the AP-1 transcription factor complex to regulate gene transcription and several differentially expressed genes have been identified in cells transformed by fos. We have extended these studies by constructing a cellular system for conditional transformation by v-fos. Using Affymetrix-based DNA microarray technology, we analyzed transcriptional changes over the course of transformation and reversion in an inducible v-fos system. RESULTS: Microarray analyses of temporal gene expression during the process of v-fos mediated cellular transformation and morphological reversion revealed a remarkably dynamic transcriptome. Of the more than 8000 genes analyzed in this study, 3766 genes were categorized into 18 gene-expression patterns by using self-organizing map analysis. By combining the analysis of gene expression profiles in stably transformed cells with the analysis of sequential expression patterns during conditional transformation, we identified a relatively small cohort of genes implicated in v-fos mediated cellular transformation. CONCLUSION: This approach defines a general conditional cell transformation system that can be used to study the endogenous transcription regulatory mechanisms involved in transformation and tumorigenesis. In addition, this study is the first reported analysis of dynamic changes in gene expression throughout experimentally controlled morphological transformation mediated by v-fos

Identification of Novel High-Frequency DNA Methylation Changes in Breast Cancer

Recent data have revealed that epigenetic alterations, including DNA methylation and chromatin structure changes, are among the earliest molecular abnormalities to occur during tumorigenesis. The inherent thermodynamic stability of cytosine methylation and the apparent high specificity of the alterations for disease may accelerate the development of powerful molecular diagnostics for cancer. We report a genome-wide analysis of DNA methylation alterations in breast cancer. The approach efficiently identified a large collection of novel differentially DNA methylated loci (∼200), a subset of which was independently validated across a panel of over 230 clinical samples. The differential cytosine methylation events were independent of patient age, tumor stage, estrogen receptor status or family history of breast cancer. The power of the global approach for discovery is underscored by the identification of a single differentially methylated locus, associated with the GHSR gene, capable of distinguishing infiltrating ductal breast carcinoma from normal and benign breast tissues with a sensitivity and specificity of 90% and 96%, respectively. Notably, the frequency of these molecular abnormalities in breast tumors substantially exceeds the frequency of any other single genetic or epigenetic change reported to date. The discovery of over 50 novel DNA methylation-based biomarkers of breast cancer may provide new routes for development of DNA methylation-based diagnostics and prognostics, as well as reveal epigenetically regulated mechanism involved in breast tumorigenesis

Cysteine 64 of Ref-1 Is Not Essential for Redox Regulation of AP-1 DNA Binding

Ref-1 participates in DNA repair as well as in redox regulation of transcription factor function. The redox function of Ref-1 involves reduction of oxidized cysteine residues within the DNA binding domains of several transcription factors, including Fos and Jun. Reduction of these residues is required for DNA binding, providing a redox-dependent mechanism for regulation of target gene expression. Previous in vitro studies implicated cysteine 65 of human Ref-1 (cysteine 64 of mouse Ref-1) as the redox catalytic site. We analyzed the in vivo role of cysteine 64 in redox regulation of AP-1 activity by introducing a cysteine-to-alanine point mutation into the endogenous mouse Ref-1 gene (ref-1(C64A)). Unlike Ref-1 null mice, which die very early in embryonic development, homozygous ref-1(C64A) mice are viable, they survive to normal life expectancy, and they display no overt abnormal phenotype. Although Ref-1 provides the major AP-1-reducing activity in murine cells, ref-1(C64A) cells retain normal levels of endogenous AP-1 DNA binding activity in vivo as well as normal Fos- and Jun-reducing activity in vitro. These results demonstrate that Ref-1 cysteine 64/65 is not required for redox regulation of AP-1 DNA binding in vivo, and they challenge previous hypotheses regarding the mechanism by which Ref-1 regulates the redox-dependent activity of specific transcription factors

Development and applications of the Oil Palm 78K Infinium® HD SNP Array for linkage analysis and chromosome scanning

High-throughput and high-density (HD) genetic marker genotyping systems are critical to optimize the efficiency of oil palm breeding and improvement programmes. This study reports the development of the 78 K Infinium® HD customized SNP array, which was used to genotype a thousand palms of a commercial Deli dura x AVROS pisifera family. A total 64,108 (∼82.0%) polymorphic SNP markers were identified of which, 57, 465 (89.6%) were mapped onto the genetic map that has the largest number of markers published so far in oil palm and holds 14,781 SNPs on 2,363 orphan scaffolds (whose chromosomal locations were unknown), which will improve the existing oil palm reference genome (EG5.1). The SNPs were highly informative based on the parent-to-progeny allelic inheritance analysis. The data demonstrated that 4.3% of the progeny resulted from unintentional self-fertilization of the dura female parent. These unintended ‘selfs’ are highly inbred, which will affect their yield. This study also for the first time, describes the homozygosity in the Deli dura and AVROS pisifera, two important parental lines widely used in commercial seed production. As expected, both the parental palms were highly homozygous, having 138 Mb homozygous regions in common, with 70.3% identical alleles. Such a detailed genetic analysis of the individual palm has been made possible with this customized HD SNP array, which will be a valuable tool for routine application in oil palm improvement programmes. The strategy used to design and apply the array will also be of interest for wider scientific research