@article{RossowVeitlVorlovaetal.2018, author = {Rossow, Leonie and Veitl, Simona and Vorlov{\´a}, Sandra and Wax, Jacqueline K. and Kuhn, Anja E. and Maltzahn, Verena and Upcin, Berin and Karl, Franziska and Hoffmann, Helene and G{\"a}tzner, Sabine and Kallius, Matthias and Nandigama, Rajender and Scheld, Daniela and Irmak, Ster and Herterich, Sabine and Zernecke, Alma and Erg{\"u}n, S{\"u}leyman and Henke, Erik}, title = {LOX-catalyzed collagen stabilization is a proximal cause for intrinsic resistance to chemotherapy}, series = {Oncogene}, volume = {37}, journal = {Oncogene}, doi = {10.1038/s41388-018-0320-2}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-227008}, pages = {4921-4940}, year = {2018}, abstract = {The potential of altering the tumor ECM to improve drug response remains fairly unexplored. To identify targets for modification of the ECM aiming to improve drug response and overcome resistance, we analyzed expression data sets from pre-treatment patient cohorts. Cross-evaluation identified a subset of chemoresistant tumors characterized by increased expression of collagens and collagen-stabilizing enzymes. We demonstrate that strong collagen expression and stabilization sets off a vicious circle of self-propagating hypoxia, malignant signaling, and aberrant angiogenesis that can be broken by an appropriate auxiliary intervention: Interfering with collagen stabilization by inhibition of lysyl oxidases significantly enhanced response to chemotherapy in various tumor models, even in metastatic disease. Inhibition of collagen stabilization by itself can reduce or enhance tumor growth depending on the tumor type. The mechanistical basis for this behavior is the dependence of the individual tumor on nutritional supply on one hand and on high tissue stiffness for FAK signaling on the other.}, language = {en} } @article{UpcinHenkeKleefeldtetal.2021, author = {Upcin, Berin and Henke, Erik and Kleefeldt, Florian and Hoffmann, Helene and Rosenwald, Andreas and Irmak-Sav, Ster and Aktas, Huseyin Bertal and R{\"u}ckschloß, Uwe and Erg{\"u}n, S{\"u}leyman}, title = {Contribution of adventitia-derived stem and progenitor cells to new vessel formation in tumors}, series = {Cells}, volume = {10}, journal = {Cells}, number = {7}, doi = {10.3390/cells10071719}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-242577}, year = {2021}, abstract = {Blocking tumor vascularization has not yet come to fruition to the extent it was hoped for, as angiogenesis inhibitors have shown only partial success in the clinic. We hypothesized that under- appreciated vascular wall-resident stem and progenitor cells (VW-SPCs) might be involved in tumor vascularization and influence effectiveness of anti-angiogenic therapy. Indeed, in patient samples, we observed that vascular adventitia-resident CD34\(^+\) VW-SPCs are recruited to tumors in situ from co-opted vessels. To elucidate this in detail, we established an ex vivo model using concomitant embedding of multi-cellular tumor spheroids (MCTS) and mouse aortic rings (ARs) into collagen gels, similar to the so-called aortic ring assay (ARA). Moreover, ARA was modified by removing the ARs' adventitia that harbors VW-SPCs. Thus, this model enabled distinguishing the contribution of VW-SPCs from that of mature endothelial cells (ECs) to new vessel formation. Our results show that the formation of capillary-like sprouts is considerably delayed, and their number and network formation were significantly reduced by removing the adventitia. Substituting iPSC-derived neural spheroids for MCTS resulted in distinct sprouting patterns that were also strongly influenced by the presence or absence of VW-SPCs, also underlying the involvement of these cells in non-pathological vascularization. Our data suggest that more comprehensive approaches are needed in order to block all of the mechanisms contributing to tumor vascularization.}, language = {en} } @article{AktasUpcinHenkeetal.2019, author = {Aktas, Bertal H. and Upcin, Berin and Henke, Erik and Padmasekar, Manju and Qin, Xuebin and Erg{\"u}n, S{\"u}leyman}, title = {The Best for the Most Important: Maintaining a Pristine Proteome in Stem and Progenitor Cells}, series = {Stem Cells International}, journal = {Stem Cells International}, doi = {10.1155/2019/1608787}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-227769}, pages = {1-20}, year = {2019}, abstract = {Pluripotent stem cells give rise to reproductively enabled offsprings by generating progressively lineage-restricted multipotent stem cells that would differentiate into lineage-committed stem and progenitor cells. These lineage-committed stem and progenitor cells give rise to all adult tissues and organs. Adult stem and progenitor cells are generated as part of the developmental program and play critical roles in tissue and organ maintenance and/or regeneration. The ability of pluripotent stem cells to self-renew, maintain pluripotency, and differentiate into a multicellular organism is highly dependent on sensing and integrating extracellular and extraorganismal cues. Proteins perform and integrate almost all cellular functions including signal transduction, regulation of gene expression, metabolism, and cell division and death. Therefore, maintenance of an appropriate mix of correctly folded proteins, a pristine proteome, is essential for proper stem cell function. The stem cells' proteome must be pristine because unfolded, misfolded, or otherwise damaged proteins would interfere with unlimited self-renewal, maintenance of pluripotency, differentiation into downstream lineages, and consequently with the development of properly functioning tissue and organs. Understanding how various stem cells generate and maintain a pristine proteome is therefore essential for exploiting their potential in regenerative medicine and possibly for the discovery of novel approaches for maintaining, propagating, and differentiating pluripotent, multipotent, and adult stem cells as well as induced pluripotent stem cells. In this review, we will summarize cellular networks used by various stem cells for generation and maintenance of a pristine proteome. We will also explore the coordination of these networks with one another and their integration with the gene regulatory and signaling networks.}, language = {en} }