Menstrual blood-derived endometrial stem cells ameliorate the viability of ovarian granulosa cells injured by cisplatin through activating autophagy

Abstract

Although the cancer incidence showed a yearly increasing trend, the long-term survival rate of cancer patients significantly increased with the continuous improvements in cancer diagnosis and treatment. Therefore, recent strategies for cancer treatment not only focus on improving the survival rate of patients but also simultaneously consider the life quality of cancer patients, especially for those with fertility requirements. Stem cell-based therapies have exhibited promising improvement in various disease treatments, and provide hope for diseases without effective treatment. Menstrual blood-derived endometrial stem cells (MenSCs) can be noninvasively and periodically obtained from discarded menstrual blood samples and exhibit high proliferative capacity, low immunogenicity and autologous transplantation. As expected, MenSCs treatment effectively improved the viability of cisplatin-injured ovarian granulosa cells (GCs) and significantly upregulated their antiapoptotic capacity. Further results demonstrated that MenSCs treatment significantly upregulated autophagy activity in cisplatin-injured ovarian GCs, and the degree of autophagy activation was positively correlated with the viability improvement of ovarian GCs, while autophagy inhibitors significantly impaired MenSC-promoted viability improvement of cisplatin-injured ovarian GCs. Additionally, MenSCs treatment can also significantly promote the proliferation of normal GCs by activating the PI3K/Akt signaling pathway. Conclusively, MenSCs treatment not only enhanced the antiapoptotic capacity and survival of cisplatin-injured ovarian GCs by upregulating autophagy activity but also improved the viability of normal ovarian GCs by activating the PI3K/Akt signal pathway. These results provide a theoretical and experimental foundation for the clinical application of MenSCs in improving chemotherapy-induced ovarian injury and delaying ovarian senescence.