Your search keyword '"Ok Jae Koo"' showing total 2 results

1. Optimized Regeneration of Petunia Protoplast and Its Association with Tissue Identity Regulators

Author

Luhua Tu, Saminathan Subburaj, Kayoun Lee, Yongsam Jeon, Fanzhuang Yan, Jian Yao, Young-Sun Kim, Ok-Jae Koo, and Geung-Joo Lee

Subjects

dedifferentiation, organogenesis, petunia, protoplast, regeneration, Plant culture, SB1-1110

Abstract

The popular ornamental plant Petunia is also a valuable model plant in tissue culture. Cellular conversions during differentiation and regeneration have been investigated using various combinations of phytohormones; however, studies on genes for reprogramming toward desired tissue identities have been limited. In this study, we isolated Petunia protoplasts and cultured them in the callus, rooting, or shooting stages, which were used to establish the optimal protoplast culture conditions and to identify genes that epigenetically function as tissue identifiers. The optimal conditions for plasmolysis and enzyme digestion to obtain healthy protoplasts were compared, in which combinations of Viscozyme, Celluclast, and Pectinex (VCP) enzymes were more efficient in isolating protoplasts when followed by 21 to 25% sucrose purification and washing processes. The filtered and washed protoplasts started to divide at 1 day and developed into colonies after 3 weeks of culture, which showed higher efficiency in the Murashige and Skoog (MS) salt culture media compared to that in the Kao and Michayluk (KM) salt media. The pluripotent colonies formed calli on the solid medium supplemented with 3% sucrose after 4 weeks, and were destined to the same cell mass, rooting, or shooting on the regeneration medium. Three epigenetic controllers, ATXR2, ATX4A, and ATX4B, were highly expressed in calli, shoots, and organs of shoots and roots, respectively, confirming that dedifferentiation and regeneration of tissue identity is plastic.

Published

2023

2. PRRX1 is a master transcription factor of stromal fibroblasts for myofibroblastic lineage progression

Author

Keun-Woo Lee, So-Young Yeo, Jeong-Ryeol Gong, Ok-Jae Koo, Insuk Sohn, Woo Yong Lee, Hee Cheol Kim, Seong Hyeon Yun, Yong Beom Cho, Mi-Ae Choi, Sugyun An, Juhee Kim, Chang Ohk Sung, Kwang-Hyun Cho, and Seok-Hyung Kim

Subjects

Mice, Multidisciplinary, Cancer-Associated Fibroblasts, Neoplasms, Animals, General Physics and Astronomy, General Chemistry, Fibroblasts, Myofibroblasts, General Biochemistry, Genetics and Molecular Biology, Transcription Factors

Abstract

Although stromal fibroblasts play a critical role in cancer progression, their identities remain unclear as they exhibit high heterogeneity and plasticity. Here, a master transcription factor (mTF) constructing core-regulatory circuitry, PRRX1, which determines the fibroblast lineage with a myofibroblastic phenotype, is identified for the fibroblast subgroup. PRRX1 orchestrates the functional drift of fibroblasts into myofibroblastic phenotype via TGF-β signaling by remodeling a super-enhancer landscape. Such reprogrammed fibroblasts have myofibroblastic functions resulting in markedly enhanced tumorigenicity and aggressiveness of cancer. PRRX1 expression in cancer-associated fibroblast (CAF) has an unfavorable prognosis in multiple cancer types. Fibroblast-specific PRRX1 depletion induces long-term and sustained complete remission of chemotherapy-resistant cancer in genetically engineered mice models. This study reveals CAF subpopulations based on super-enhancer profiles including PRRX1. Therefore, mTFs, including PRRX1, provide another opportunity for establishing a hierarchical classification system of fibroblasts and cancer treatment by targeting fibroblasts.

Published

2022