Ets-related gene (ERG) is a member of the ETS transcription factor gene family located on Hsa21. ERG is known to have a crucial role in establishing definitive hematopoiesis and is required for normal megakaryopoiesis. Truncated forms of ERG are associated with multiple cancers such as Ewing's sarcoma, prostate cancer, and leukemia as part of oncogenic fusion translocations. Increased expression of ERG is highly indicative of poor prognosis in acute myeloid leukemia and ERG is expressed in acute megakaryoblastic leukemia (AMKL); however, it is unclear if expression of ERG per se has a leukemogenic activity. We show that ectopic expression of ERG in fetal hematopoietic progenitors promotes megakaryopoiesis and that ERG alone acts as a potent oncogene in vivo leading to rapid onset of leukemia in mice. We observe that the endogenous ERG is required for the proliferation and maintenance of AMKL cell lines. ERG also strongly cooperates with the GATA1s mutated protein, found in Down syndrome AMKL, to immortalize megakaryocyte progenitors, suggesting that the additional copy of ERG in trisomy 21 may have a role in Down syndrome AMKL. These data suggest that ERG is a hematopoietic oncogene that may play a direct role in myeloid leukemia pathogenesis. [Cancer Res 2009;69(11):4665-73]
Wednesday, June 24, 2009
[Medical_Sciences] Functional genomic analysis of amniotic fluid cell-free mRNA suggests that oxidative stress is significant in Down syndrome fetuses
To characterize the differences between second trimester Down syndrome (DS) and euploid fetuses, we used Affymetrix microarrays to compare gene expression in uncultured amniotic fluid supernatant samples. Functional pathway analysis highlighted the importance of oxidative stress, ion transport, and G protein signaling in the DS fetuses. Further evidence supporting these results was derived by correlating the observed gene expression patterns to those of small molecule drugs via the Connectivity Map. Our results suggest that there are secondary adverse consequences of DS evident in the second trimester, leading to testable hypotheses about possible antenatal therapy for DS.
Inverted duplications on acentric markers: mechanism of formation
Acentric inverted duplication (inv dup) markers, the largest group of chromosomal abnormalities with neocentromere formation, are found in patients both with idiopathic mental retardation and with cancer. The mechanism of their formation has been investigated by analyzing the breakpoints and the genotypes of 12 inv dup marker cases (three trisomic, six tetrasomic, two polysomic and one X chromosome derived marker) using a combination of fluorescence in situ hybridization, quantitative SNP array and microsatellite analysis. Inv dup markers were found to form either symmetrically with one breakpoint or asymmetrically with two distinct breakpoints. Genotype analyses revealed that all inv dup markers formed from one single chromatid end. This observation is incompatible with the previously suggested model by which the acentric inv dup markers form through inter-chromosomal U-type exchange. On the basis of the identification of DNA sequence motifs with inverted homologies within all observed breakpoint regions, a new general mechanism is proposed for the acentric inv dup marker formation: following a double-strand break an acentric fragment forms, during either meiosis or mitosis. The open DNA end of the acentric fragment is stabilized by the formation of an intra-chromosomal loop promoted by the presence of sequences with inverted homologies. Likely coinciding with the neocentromere formation, this stabilized fragment is duplicated during an early mitotic event, insuring the marker’s survival during cell division and its presence in all cells.
"Statistical model for whole genome sequencing and its application to minimally invasive diagnosis of fetal genetic disease
There is currently great interest in the development of methods for the minimally invasive diagnosis of fetal genetic disease using cell-free DNA from maternal plasma samples obtained in the first trimester of pregnancy. With the rapid development of high-throughput sequencing technology, the possibility of detecting the presence of trisomy fetal genomes in the maternal plasma DNA sample has recently been explored. The major concern of this whole genome sequencing approach is that, while detecting the karyotype of the fetal genome from the maternal plasma requires extremely high accuracy of copy number estimation, the majority of the available high-throughput sequencing technologies require polymerase chain reaction (PCR) and are subject to the substantial bias that is inherent to the PCR process. We introduce a novel and sophisticated statistical model for the whole genome sequencing data, and based on this model, develop a highly sensitive method of Minimally Invasive Karyotyping (MINK) for the diagnosis of the fetal genetic disease. Specifically we demonstrate, by applying our statistical method to ultra high-throughput whole sequencing data, that trisomy 21 can be detected in a minor (‘fetal’) genome when it is mixed into a major (‘maternal’) background genome at frequencies as low as 5%. This observation provides additional proof of concept and justification for the further development of this method towards its eventual clinical application. Here, we describe the statistical and experimental methods that illustrate this approach and discuss future directions for technical development and potential clinical applications.
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DNA Methylation Analysis of Chromosome 21 Gene Promoters at Single Base Pair and Single Allele Resolution
Epigenetics is defined as the inheritance of changes in gene function without changing the DNA sequence. Epigenetic signals comprise methylation of cytosine bases of the DNA and chemical modifications of the histone proteins. DNA methylation plays important roles in development and disease processes. To investigate the biological role of DNA methylation, we analyzed DNA methylation patterns of 190 gene promoter regions on chromosome 21 in five human cell types. Our results show that average DNA methylation levels are distributed bimodally with enrichment of highly methylated and unmethylated sequences, indicating that DNA methylation acts in a switch-like manner. Consistent with the well-established role of DNA methylation in gene silencing, we found DNA methylation in promoter regions strongly correlated with absence of gene expression and low levels of additional activating epigenetic marks. Although methylation levels of individual cells in one tissue are very similar, we observed differences in DNA methylation when comparing different cell types in 43% of all regions analyzed. This finding is in agreement with a role of DNA methylation in cellular development. We identified three cases of genes that are differentially methylated in both alleles that illustrate the tight interplay of genetic and epigenetic processes.