Lkb1 deletion in periosteal mesenchymal progenitors induces osteogenic tumors through mTORC1 activation
Yujiao Han, Heng Feng, Jun Sun, Xiaoting Liang, Zhuo Wang, Wenhui Xing, Qinggang Dai, Yang Yang, Anjia Han, Zhanying Wei, Qing Bi, Hongbin Ji, Tiebang Kang, Weiguo Zou
Yujiao Han, Heng Feng, Jun Sun, Xiaoting Liang, Zhuo Wang, Wenhui Xing, Qinggang Dai, Yang Yang, Anjia Han, Zhanying Wei, Qing Bi, Hongbin Ji, Tiebang Kang, Weiguo Zou
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Research Article Bone biology Oncology

Lkb1 deletion in periosteal mesenchymal progenitors induces osteogenic tumors through mTORC1 activation

Abstract

Bone osteogenic sarcoma has a poor prognosis, as the exact cell of origin and the signaling pathways underlying tumor formation remain undefined. Here, we report an osteogenic tumor mouse model based on the conditional knockout of liver kinase b1 (Lkb1, also known as Stk11) in Cathepsin K–Cre–expressing (Ctsk-Cre–expressing) cells. Lineage-tracing studies demonstrated that Ctsk-Cre could label a population of periosteal cells. The cells functioned as mesenchymal progenitors with regard to markers and functional properties. LKB1 deficiency increased proliferation and osteoblast differentiation of Ctsk+ periosteal cells, while downregulation of mTORC1 activity, using a Raptor genetic mouse model or mTORC1 inhibitor treatment, ameliorated tumor progression of Ctsk-Cre Lkb1fllfl mice. Xenograft mouse models using human osteosarcoma cell lines also demonstrated that LKB1 deficiency promoted tumor formation, while mTOR inhibition suppressed xenograft tumor growth. In summary, we identified periosteum-derived Ctsk-Cre–expressing cells as a cell of origin for osteogenic tumor and suggested the LKB1/mTORC1 pathway as a promising target for treatment of osteogenic tumor.

Authors

Yujiao Han, Heng Feng, Jun Sun, Xiaoting Liang, Zhuo Wang, Wenhui Xing, Qinggang Dai, Yang Yang, Anjia Han, Zhanying Wei, Qing Bi, Hongbin Ji, Tiebang Kang, Weiguo Zou

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Figure 5

LKB1-deficient Ctsk+ cells display higher self-renewal and osteoblast differentiation ability.

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LKB1-deficient Ctsk+ cells display higher self-renewal and osteoblast di...
(A and B) Immunostaining of PCNA in Ctsk-Cre–expressing cells in Ctsk-CKO mice showed increased proliferation rate. Scale bar: 50 μm. (C and D) Plate colony formation of Ctsk-Ai9 cells purified via flow cytometry from the cortical bone of Ctsk-Ctrl; Rosa26-Ai9 and Ctsk-CKO; Rosa26-Ai9 mice, showing an enhanced proliferation rate of cells from Ctsk-CKO; Rosa-Ai9 mice. Scale bar: 10 μm. (E and F) Confocal images showing that expanded Ctsk-Cre–positive cells (red) in the cortical bone of Ctsk-CKO; Rosa26-Ai9 tibiae displayed a higher frequency of CD44-positive cells (white arrows). Scale bar: 20 μm. (GI) Deletion of Lkb1 in the periosteal cortical bone cells via Cre adenovirus (Adv-Cre) leads to increased osteoblast differentiation monitored by ALP staining. (G) Supernatant ALP activity relative to the cell number measured via Alamar blue (Ala.Blue) (H) and marker gene expression (I) after 7-day induction. (JO) Transplantation of periosteum-derived cells from 4-week-old Ctsk-Ctrl; Rosa-Ai9 and Ctsk-CKO; Rosa-Ai9 mice to the nude mice subcutaneously. (K) Weight of bone organoids formed by Ctsk-Ctrl; Rosa-Ai9 (3/5) and Ctsk-CKO; Rosa-Ai9 (5/5) cells. (L and M) Representative images of H&E staining (L) and von Kossa staining (M) of the bone organoids. Scale bars: 500 μm (left); 20 μm (right). (N) Confocal imaging showing Ctsk-Ai9+ cells were involved in osteoid formation. Scale bar: 200 μm. (O) Immunostaining of osteogenic marker, OSX (green), and OPN (green) showing osteogenic potential of transplanted Ctsk-Ai9 cells (white arrows). Scale bar: 20 μm. Data are represented as mean ± SEM. **P < 0.01; ***P < 0.001, unpaired Student’s t test.