To bioengineer ectodermal organs such as teeth and whisker follicles, we developed a three-dimensional organ-germ culture method. The bioengineered tooth germ generated a structurally correct tooth, after both in vitro organ culture as well as transplantation under a tooth cavity in vivo, showing penetration of blood vessels and nerve fibers. Our method provides a substantial advance in the development of bioengineered organ replacement strategies and regenerative therapies.
Eukaryotic cells have signalling pathways from the endoplasmic reticulum (ER) to cytosol and nuclei, to avoid excess accumulation of unfolded proteins in the ER. We previously identified a new type of ER stress transducer, OASIS, a bZIP (basic leucine zipper) transcription factor, which is a member of the CREB/ATF family and has a transmembrane domain. OASIS is processed by regulated intramembrane proteolysis (RIP) in response to ER stress, and is highly expressed in osteoblasts. OASIS(-/-) mice exhibited severe osteopenia, involving a decrease in type I collagen in the bone matrix and a decline in the activity of osteoblasts, which showed abnormally expanded rough ER, containing of a large amount of bone matrix proteins. Here we identify the gene for type 1 collagen, Col1a1, as a target of OASIS, and demonstrate that OASIS activates the transcription of Col1a1 through an unfolded protein response element (UPRE)-like sequence in the osteoblast-specific Col1a1 promoter region. Moreover, expression of OASIS in osteoblasts is induced by BMP2 (bone morphogenetic protein 2), the signalling of which is required for bone formation. Additionally, RIP of OASIS is accelerated by BMP2 signalling, which causes mild ER stress. Our studies show that OASIS is critical for bone formation through the transcription of Col1a1 and the secretion of bone matrix proteins, and they reveal a new mechanism by which ER stress-induced signalling mediates bone formation.
Many tissues have a specific signal transduction system for endoplasmic reticulum (ER) dysfunction; however, the mechanisms underlying the ER stress response in cartilage remain unclear. BBF2H7 (BBF2 human homologue on chromosome 7), an ER-resident basic leucine zipper transcription factor, is activated in response to ER stress and is highly expressed in chondrocytes. In this study, we generated Bbf2h7(-/-) mice to assess the in vivo function of BBF2H7. The mice showed severe chondrodysplasia and died by suffocation shortly after birth because of an immature chest cavity. The cartilage showed a lack of typical columnar structure in the proliferating zone and a decrease in the size of the hypertrophic zone, resulting in a significant reduction of extracellular matrix proteins. Interestingly, proliferating chondrocytes showed abnormally expanded ER, containing aggregated type II collagen (Col2) and cartilage oligomeric matrix protein (COMP). We identified Sec23a, which encodes a coat protein complex II component responsible for protein transport from the ER to the Golgi, as a target of BBF2H7, which directly bound to a CRE-like sequence in the promoter region of Sec23a to activate its transcription. When Sec23a was introduced to Bbf2h7(-/-) chondrocytes, the impaired transport and secretion of cartilage matrix proteins was totally restored, indicating that by activating protein secretion the BBF2H7-Sec23a pathway has a crucial role in chondrogenesis. Our findings provide a new link by which ER stress is converted to signalling for the activation of ER-to-Golgi trafficking.
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