笠嶋 克巳

Ras gene mutations are frequently observed in many types of cancers. However, there are currently no effective anticancer drugs against Ras-induced cancers. Therefore, identifying the downstream effectors of the Ras signaling pathway can facilitate the development of promising novel therapeutic approaches. We previously showed that oncogenic Ras induces the expression of the receptor tyrosine kinase c-Mer proto-oncogene tyrosine kinase (MerTK) in an interleukin-1 family member NF-HEV/IL-33-dependent manner and that IL-33 and MerTK contribute to oncogenic Ras-induced cell migration. In the present study, we purified the MerTK complex from NIH-3T3 cells transformed by the expression of oncogenic Ras, H-Ras (G12V). Mass spectrometric analysis identified STK38 (also known as NDR1) as a candidate binding partner for MerTK. STK38 is a serine/threonine protein kinase that plays diverse roles in normal and cancerous cells. In addition to MerTK knockdown, STK38 knockdown effectively attenuated the H-Ras (G12V)-induced migration of NIH-3T3 cells. STK38 kinase activity is required for oncogenic Ras-induced cell migration and MerTK tyrosine phosphorylation. Furthermore, MerTK or STK38 knockdown attenuated the activation of Rac1 and Cdc42. Taken together, these results revealed a novel role for STK38 in oncogenic Ras-induced enhanced cell migration, which may be useful for developing novel therapeutic strategies targeting Ras-mutated cells.

Epigenetic regulation via epigenetic factors in collaboration with tissue-specific transcription factors is curtail for establishing functional organ systems during development. Brain development is tightly regulated by epigenetic factors, which are coordinately activated or inactivated during processes, and their dysregulation is linked to brain abnormalities and intellectual disability. However, the precise mechanism of epigenetic regulation in brain development and neurogenesis remains largely unknown. Here, we show that Tip60/KAT5 deletion in neural stem/progenitor cells (NSCs) in mice results in multiple abnormalities of brain development. Tip60-deficient embryonic brain led to microcephaly, and proliferating cells in the developing brain were reduced by Tip60 deficiency. In addition, neural differentiation and neuronal migration were severely affected in Tip60-deficient brains. Following neurogenesis in developing brains, gliogenesis started from the earlier stage of development in Tip60-deficient brains, indicating that Tip60 is involved in switching from neurogenesis to gliogenesis during brain development. It was also confirmed in vitro that poor neurosphere formation, proliferation defects, neural differentiation defects, and accelerated astrocytic differentiation in mutant NSCs are derived from Tip60-deficient embryonic brains. This study uncovers the critical role of Tip60 in brain development and NSC maintenance and function in vivo and in vitro.

Mitochondrial dysfunction is significantly associated with neurological deficits and age-related neurological diseases. While mitochondria are dynamically regulated and properly maintained during neurogenesis, the manner in which mitochondrial activities are controlled and contribute to these processes is not fully understood. Mitochondrial transcription factor A (TFAM) contributes to mitochondrial function by maintaining mitochondrial DNA (mtDNA). To clarify how mitochondrial dysfunction affects neurogenesis, we induced mitochondrial dysfunction specifically in murine neural stem cells (NSCs) by inactivating Tfam. Tfam inactivation in NSCs resulted in mitochondrial dysfunction by reducing respiratory chain activities and causing a severe deficit in neural differentiation and maturation both in vivo and in vitro. Brain tissue from Tfam-deficient mice exhibited neuronal cell death primarily at layer V and microglia were activated prior to cell death. Cultured Tfam-deficient NSCs showed a reduction in reactive oxygen species produced by the mitochondria. Tfam inactivation during neurogenesis resulted in the accumulation of ATF4 and activation of target gene expression. Therefore, we propose that the integrated stress response (ISR) induced by mitochondrial dysfunction in neurogenesis is activated to protect the progression of neurodegenerative diseases.