In IGF-I receptor-deficient leiomyosarcoma cells autocrine IGF-II induces cell invasion and protection from apoptosis via the insulin receptor isoform A.

One of the two isoforms of the human insulin receptor (isoform A or IR-A) binds IGF-II with high affinity and is predominantly expressed in fetal tissues and malignant cells. We evaluated the biological relevance of IR-A in human myosarcoma cells. Six myosarcoma cell lines were studied. All produced high amounts of IGF-II and five of them predominantly expressed IR-A. SKUT-1 leiomyosarcoma cells, that do not express the IGF-IR, were identified as a suitable model to study the effects of IR-A in the absence of the interference of IGF-IR. In these cells, which express high levels of IR with an IR-A relative abundance of approximately 95%, IGF-II elicits biological effects exclusively via IR-A activation and IGF-I is almost ineffective. Blockade of autocrine IGF-II reduced unstimulated cell viability and migration. Although both insulin and IGF-II activate IR-A, these two ligands showed a different ability to activate different intracellular signaling pathways and to elicit different biological effects. Insulin was more potent than IGF-II in activating the PI3-K/Akt pathway and in protecting cells from apoptosis. In contrast, IGF-II was more potent than insulin in activating the Shc/ERK pathway and in stimulating cell migration. These data indicate that IGF-II sensitive IR-A is the predominant IR isoform in a variety of myosarcoma cells. In SKUT-1 leiomyoma cells this fetal IR isoform may vicariate the IGF-IR for cell response to both insulin and IGF-II. Acting on the same IR-A receptor IGF-II is more potent than insulin in stimulating cancer cell migration.