Elevated expression of endoglin, a component of the TGF-beta-receptor complex, correlates with proliferation of tumor endothelial cells.

Endoglin/CD105 is a membrane protein involved in the TGF-beta receptor signalling pathway. Endoglin expression has been reported to be selective for a few cell types, in particular endothelial cells, although a number of conflicting reports have been published. In this study, we performed a detailed analysis of endoglin expression in human lung tumors and different tumor and endothelial cell lines, employing reverse-transcriptase-polymerase-chain reaction as well as immunoblotting and immunohistochemistry using verified antibodies to endoglin. Our data show a clearly preferential expression of both endoglin mRNA and protein in endothelial cells. In tumors, endoglin expression was strongly elevated in the angiogenic endothelium at the tumor edges. In agreement with this observation, we find a clear correlation between endoglin expression and markers of proliferation, such as cyclin A and Ki-67, suggesting that endoglin expression is linked to cell-cycle regulation. These findings not only resolve some of the discrepancies in the literature, but also provide the basis for further applications making use of its selective localization and expression in the tumor vasculature.

Cell type specificity of the human endoglin promoter.

Endoglin is a component of the transforming growth factor-beta receptor complex whose expression is limited to a small number of cell types, including endothelial cells (ECs), activated monocytes, tissue macrophages and erythroid precursors. Of particular interest is its preferential expression in the vasculature of many malignant tumors, especially in view of potential therapeutic applications. We have cloned the human endoglin promoter, analyzed its structure and demonstrate that the isolated genomic fragment shows strong promoter activity in ECs (compared to other known EC-selective promoters), but not in epithelial cells and fibroblasts. These findings suggest that the endoglin promoter may prove a useful tool for the transcriptional targeting of ECs by gene therapy. We also determined the domains that are responsible for both efficient transcription and the observed preferential activity in ECs. The region around the major site of transcription initiation was found to be essential for transcription in both ECs and non-ECs. In contrast, cell type specificity does not appear to be governed by a single mechanism, but rather seems to be due to functionally distinct regulatory mechanisms acting on different upstream sequences.

A novel, transformation-relevant activation domain in Fos proteins.

We have previously demonstrated that transformation by Fos is critically dependent on an intact DNA-binding domain (bZip) and a functional N-terminal transactivation motif (N-TM). We now show that a novel motif (C-terminal transactivation motif [C-TM]) near the C terminus also plays an important role in both transformation and the activation of AP1-dependent transcription and that the hydrophobic amino acids in the C-TM are functionally essential. The C-TM is the most crucial element in the C-terminal transactivation domain in Fos, as indicated by its relative strength and context-independent function. The C-TM is clearly different from the previously identified HOB2 domain, located N terminally to the C-TM, and the C-terminally positioned TATA-binding protein-binding domain. We also show that the C-terminal transactivation domain strongly synergizes with the HOB1-like N-TM, even when both domains are present on different proteins within a dimeric complex, and that the C-TM plays a crucial role in this cooperation. These observations can be corroborated in a model in which multiple contacts with the basal machinery are established either to stabilize the transcription complex or to facilitate its sequential assembly.