Interplay between desmoglein2 and hypoxia controls metastasis in breast cancer.

Metastasis is the major cause of cancer death. An increased level of circulating tumor cells (CTCs), metastatic cancer cells that have intravasated into the circulatory system, is particularly associated with colonization of distant organs and poor prognosis. However, the key factors required for tumor cell dissemination and colonization remain elusive. We found that high expression of desmoglein2 (DSG2), a component of desmosome-mediated intercellular adhesion complexes, promoted tumor growth, increased the prevalence of CTC clusters, and facilitated distant organ colonization. The dynamic regulation of DSG2 by hypoxia was key to this process, as down-regulation of DSG2 in hypoxic regions of primary tumors led to elevated epithelial-mesenchymal transition (EMT) gene expression, allowing cells to detach from the primary tumor and undergo intravasation. Subsequent derepression of DSG2 after intravasation and release of hypoxic stress was associated with an increased ability to colonize distant organs. This dynamic regulation of DSG2 was mediated by Hypoxia-Induced Factor1α (HIF1α). In contrast to its more widely observed function to promote expression of hypoxia-inducible genes, HIF1α repressed DSG2 by recruitment of the polycomb repressive complex 2 components, EZH2 and SUZ12, to the DSG2 promoter in hypoxic cells. Consistent with our experimental data, DSG2 expression level correlated with poor prognosis and recurrence risk in breast cancer patients. Together, these results demonstrated the importance of DSG2 expression in metastasis and revealed a mechanism by which hypoxia drives metastasis.

Role of stromal fibroblasts in cancer: promoting or impeding?

The basement membrane, immune cells, capillaries, fibroblasts and extracellular matrix (ECM) constitute the tumour stroma, commonly referred to as the 'reactive stroma'. The fibroblasts from the initial stages of a tumour, as the main constituents of the reactive stroma, present a different phenotype from the normal fibroblasts and play a crucial role in tumour progression. This review presents the differences between normal and tumour stromal fibroblasts and analyzes the molecular mechanisms (which involve growth factors, ECM components, matrix metalloproteinases, integrins and cell adhesion molecules) in the complex interactions between stromal fibroblasts and tumour cells. To date, several examples of heterotypic interactions between tumour stromal fibroblasts and tumour cells have supported the hypothesis that the tumour stroma promotes the growth of the tumour mass, as well as invasion and metastasis. However, it remains possible that the stroma acts essentially as a local modulator to impede tumorigenesis at an early stage and that the desmoplastic response is a host defence reaction designed to confine the developing tumour. The latter hypothesis has largely been neglected. The review aims to give a broader view on the role of stromal fibroblasts in tumour growth, invasion and metastasis.

KC21 Peptide Inhibits Angiogenesis and Attenuates Hypoxia-Induced Retinopathy.

Desmogleins (Dsg2) are the major components of desmosomes. Dsg2 has five extracellular tandem cadherin domains (EC1-EC5) for cell-cell interaction. We had previously confirmed the Dsg2 antibody and its epitope (named KC21) derived from EC2 domain suppressing epithelial-mesenchymal transition and invasion in human cancer cell lines. Here, we screened six peptide fragments derived from EC2 domain and found that KR20, the parental peptide of KC21, was the most potent one on suppressing endothelial colony-forming cell (ECFC) tube-like structure formation. KC21 peptide also attenuated migration but did not disrupt viability and proliferation of ECFCs, consistent with the function to inhibit VEGF-mediated activation of p38 MAPK but not AKT and ERK. Animal studies showed that KC21 peptides suppressed capillary growth in Matrigel implant assay and inhibited oxygen-induced retinal neovascularization. The effects were comparable to bevacizumab (Bev). In conclusion, KC21 peptide is an angiogenic inhibitor potentially useful for treating angiogenesis-related diseases.

Identification and characterization of the conserved nucleoside-binding sites in the Epstein-Barr virus thymidine kinase.

Thymidine kinase (TK), encoded by EBV (Epstein-Barr virus), is an attractive target for antiviral therapy and provides a novel approach to the treatment of EBV-associated malignancies. Despite the extensive use of nucleoside analogues for the treatment of viral infections and cancer, the structure-function relationship of EBV TK has been addressed rarely. In the absence of any structural information, we sought to identify and elucidate the functional roles of amino acids in the nucleoside-binding site using site-directed mutagenesis. Through alignment with other human herpesviral TK protein sequences, we predicted that certain conserved regions comprise the nucleoside-binding site of EBV TK and, through site-directed mutagenesis, showed significant changes in activity and binding affinity for thymidine of site 3 (-DRH-) and 4 (-VFP-) mutants. For site 3, only mutants D392E (Asp392-->Glu) and R393H retain activity, indicating that a negative charge is important for Asp392 and a positive charge is required for Arg393. The increased binding affinities of these two mutants for 3'-deoxy-2',3'-didehydrothymidine suggest that the two residues are also important for substrate selection. Interestingly, the changed metal-ion usage pattern of D392E reveals that Asp392 plays multiple roles in this region. His394 cannot be compensated by other amino acids, also indicating a crucial role. In site 4, the F402Y mutant retains full activity; however, F402S retains only 60% relative activity. Strikingly, when Phe402 is substituted with serine residue, the original preferred pyrimidine substrates, such as 3'-azido-3'-deoxythymidine, iododeoxyuridine and beta-L-5-iododioxolane uracil (L-form substrate), have decreased competitiveness with thymidine, suggesting that Phe402 plays a crucial role in substrate specificity and that the aromatic ring is important for function.