We report here the identification of an active compound 9179A as a known compound trichostatin A (TSA), and its effects on CLA-1/SR-BI expression both in HepG2 human hepatoma cells Selleckchem Fludarabine and RAW 264.7 murine macrophage cells in vitro. The results showed that the mRNA and Protein level of CLA-1/SR-BI were significantly up-regulated by 9179A both in HepG2 and RAW 264.7 cells. Corresponding to this, the uptake of Dil-HDL by both cells and the efflux of [(3)H]cholesterol by RAW
264.7 cells were increased by 9179A in close-dependent manner. ABCA1 was also increased but SR-A decreased by 9179A in RAW 264.7 cells. Using a combination of reporter assays with various deletion in CLA-1 promoter and electrophoretic mobility shift assay, we demonstrated that -419/-232 bp fragment of the CLA-1 promoter mediated (lie effects of 9179A (i.e., TSA). Together, these studies identified TSA as a novel Up-regulator of CLA-1/SR-BI both in HepG2 and RAW 264.7 cells. (C) 2008 Elsevier Ireland Ltd. All rights reserved.”
“Few ideas have gained such strong acceptance in the scientific community as the monoclonal origin of tumors; the idea that tumors start with a single mutated cell (or a single clone of cells) that go on
to accumulate additional mutations as a tumor develops. The certainty with which this concept is held by the scientific community reflects the length of time it has been unchallenged SHP099 inhibitor and the experimental difficulty in obtaining direct evidence to the contrary. Yet, recent findings regarding X chromosome inactivation patch size indicate that the X-linked marker
data previously interpreted as evidence of monoclonal tumor origin is actually more consistent with polyclonal tumor origin, a situation where two or more cells or clones of cells interact to initiate a tumor. Although most tumors show homotypy for X-linked markers (as expected given the bias conferred by X chromosome inactivation patch size), the literature contains numerous examples of tumors with X-linked marker heterotypy, examples of which encompass 24 different tumor types. Chimeric models have yielded direct unequivocal demonstrations of polyclonality in rodent and human tumors. Also, mutational data are consistent with polyclonal tumor origin. Methods that analyze levels Torin 1 of tumor-associated oncogene and tumor suppressor gene mutations demonstrate that initiated cells are much more common in normal tissues than previously realized. Also, while tumors have higher levels of mutation than normal tissues, oncogenic mutations frequently are present as subpopulations within tumors, rather than as the pure mutant populations expected to develop from a single initiated cell. Understanding the mutational basis of tumor etiology has important practical significance for assessing cancer risk, as well as in modeling and treating cancer.