Extracellular vesicle-associated tyrosine kinase-like orphan receptors ROR1 and ROR2 promote breast cancer progression
Irmer B; Efing J; Reitnauer LE; Angenendt A; Heinrichs S; Schubert A; Schulz M; Binder C; Tio J; Hansen U; Geyer C; Gerwing M; Bleckmann A; Menck K
Forschungsartikel (Zeitschrift) | Peer reviewedZusammenfassung
BACKGROUND - METHODS - RESULTS - CONCLUSIONS; Extracellular vesicles (EVs) harbor a plethora of different biomolecules, which they can transport across cells. In cancer, tumor-derived EVs thereby support the creation of a favorable tumor microenvironment. So far, EV uptake and cargo delivery into target cells have been regarded as the main mechanisms for the pro-tumoral function of EVs. To test this hypothesis, we investigated the fate of the oncogenic transmembrane Wnt tyrosine kinase-like orphan receptor 1 and 2 (ROR1, ROR2) delivered via distinct EV subpopulations to breast cancer cells and aimed to unravel their impact on tumor progression.; EVs were isolated by differential ultracentrifugation from cell culture supernatant as well as plasma samples from healthy individuals (n = 27) and breast cancer patients (n = 41). EVs were thoroughly characterized by electron microscopy, nanoparticle tracking analysis, immunoblot, and flow cytometry. ROR transfer to target cells was observed using microscopy-based assays and biodistribution experiments were conducted in syngeneic mice. EV impact on cancer cell migration and invasion was tested in functional assays.; We observed that the supernatant of ROR-overexpressing cells was sufficient for transferring the receptors to ROR-negative cells. Analyzing the secretome of the ROR-overexpressing cells, we detected a high enrichment of ROR1/2 on large and small EVs, but not on large oncosomes. Interestingly, the majority of ROR-positive EVs remained attached to the target cell surface after 24 h of stimulation and was quickly removed by treatment with trypsin. Nonetheless, ROR-positive EVs increased migration and invasion of breast cancer cells, even after chemically inhibiting EV uptake, in dependence of RhoA downstream signaling. In vivo, ROR-depleted EVs tended to distribute less into organs prone for the formation of breast cancer metastases. ROR-positive EVs were also significantly elevated in the plasma of breast cancer patients and allowed to separate them from healthy controls.; The oncogenic Wnt receptors ROR1/2 are transferred via EVs to the surface of ROR-negative cancer cells, in which they induce an aggressive phenotype supporting tumor progression. Video Abstract.
Details zur Publikation
Autor*innen der Universität Münster
| Angenendt, Allegra | Medizinische Klinik A (Med A) |
| Bleckmann, Annalen | Medizinische Klinik A (Med A) |
| Gerwing, Mirjam | Klinik für Radiologie |
| Geyer, Christiane | Klinik für Radiologie |
| Hansen, Uwe | Institut für Muskuloskelettale Medizin (IMM) |
| Heinrichs, Saskia | Medizinische Klinik A (Med A) |
| Irmer, Barnabas | Medizinische Klinik A (Med A) |
| Menck, Kerstin | Medizinische Klinik A (Med A) |
| Reitnauer, Lea Elisabeth | Medizinische Klinik A (Med A) |
| Schubert, Antonia | Münster Electrochemical Energy Technology Battery Research Center (MEET) |
| Schulz, Matthias | Institut für Neutestamentliche Textforschung (INTF) |
Promotionen, aus denen die Publikation resultiert
| Analyse von neuer Regulatoren der Biogenese und Funktion von extrazellulären Vesikeln Promovend*in: Irmer, Barnabas | Betreuer*innen: Bleckmann, Annalen; Menck, Kerstin; Grashoff, Carsten; Busch, Karin | Gutachter*innen: Bleckmann, Annalen; Grashoff, Carsten; Busch, Karin Zeitraum: 01.10.2020 - 11.06.2024 Promotionsverfahren erfolgt(e) an: Promotionsverfahren an der Universität Münster |