Literature DB >> 29748647

Isolation and functional assessment of mouse skeletal stem cell lineage.

Gunsagar S Gulati1,2, Matthew P Murphy1,2, Owen Marecic1,2, Michael Lopez1,2, Rachel E Brewer1,2, Lauren S Koepke1,2, Anoop Manjunath1,2, Ryan C Ransom1,2, Ankit Salhotra1,2, Irving L Weissman1,3,4, Michael T Longaker1,2, Charles K F Chan1,2.   

Abstract

There are limited methods available to study skeletal stem, progenitor, and progeny cell activity in normal and diseased contexts. Most protocols for skeletal stem cell isolation are based on the extent to which cells adhere to plastic or whether they express a limited repertoire of surface markers. Here, we describe a flow cytometry-based approach that does not require in vitro selection and that uses eight surface markers to distinguish and isolate mouse skeletal stem cells (mSSCs); bone, cartilage, and stromal progenitors (mBCSPs); and five downstream differentiated subtypes, including chondroprogenitors, two types of osteoprogenitors, and two types of hematopoiesis-supportive stroma. We provide instructions for the optimal mechanical and chemical digestion of bone and bone marrow, as well as the subsequent flow-cytometry-activated cell sorting (FACS) gating schemes required to maximally yield viable skeletal-lineage cells. We also describe a methodology for renal subcapsular transplantation and in vitro colony-formation assays on the isolated mSSCs. The isolation of mSSCs can be completed in 9 h, with at least 1 h more required for transplantation. Experience with flow cytometry and mouse surgical procedures is recommended before attempting the protocol. Our system has wide applications and has already been used to study skeletal response to fracture, diabetes, and osteoarthritis, as well as hematopoietic stem cell-niche interactions in the bone marrow.

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Year:  2018        PMID: 29748647      PMCID: PMC6530903          DOI: 10.1038/nprot.2018.041

Source DB:  PubMed          Journal:  Nat Protoc        ISSN: 1750-2799            Impact factor:   13.491


  36 in total

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  29 in total

1.  Hypertrophic chondrocytes serve as a reservoir for marrow-associated skeletal stem and progenitor cells, osteoblasts, and adipocytes during skeletal development.

Authors:  Jason T Long; Abigail Leinroth; Yihan Liao; Yinshi Ren; Anthony J Mirando; Tuyet Nguyen; Wendi Guo; Deepika Sharma; Douglas Rouse; Colleen Wu; Kathryn Song Eng Cheah; Courtney M Karner; Matthew J Hilton
Journal:  Elife       Date:  2022-02-18       Impact factor: 8.140

2.  Skeletal Stem Cells as the Developmental Origin of Cellular Niches for Hematopoietic Stem and Progenitor Cells.

Authors:  Thomas H Ambrosi; Charles K F Chan
Journal:  Curr Top Microbiol Immunol       Date:  2021       Impact factor: 4.291

Review 3.  The long and winding road: homeostatic and disordered haematopoietic microenvironmental niches: a narrative review.

Authors:  Suzanne M Watt
Journal:  Biomater Transl       Date:  2022-03-28

4.  Skeletal Stem Cell-Schwann Cell Circuitry in Mandibular Repair.

Authors:  R Ellen Jones; Ankit Salhotra; Kiana S Robertson; Ryan C Ransom; Deshka S Foster; Harsh N Shah; Natalina Quarto; Derrick C Wan; Michael T Longaker
Journal:  Cell Rep       Date:  2019-09-10       Impact factor: 9.423

5.  Notch-Wnt signal crosstalk regulates proliferation and differentiation of osteoprogenitor cells during intramembranous bone healing.

Authors:  S Lee; L H Remark; A M Josephson; K Leclerc; E Muiños Lopez; D J Kirby; Devan Mehta; H P Litwa; M Z Wong; S Y Shin; P Leucht
Journal:  NPJ Regen Med       Date:  2021-05-28

6.  Aged skeletal stem cells generate an inflammatory degenerative niche.

Authors:  Thomas H Ambrosi; Owen Marecic; Adrian McArdle; Rahul Sinha; Gunsagar S Gulati; Xinming Tong; Yuting Wang; Holly M Steininger; Malachia Y Hoover; Lauren S Koepke; Matthew P Murphy; Jan Sokol; Eun Young Seo; Ruth Tevlin; Michael Lopez; Rachel E Brewer; Shamik Mascharak; Laura Lu; Oyinkansola Ajanaku; Stephanie D Conley; Jun Seita; Maurizio Morri; Norma F Neff; Debashis Sahoo; Fan Yang; Irving L Weissman; Michael T Longaker; Charles K F Chan
Journal:  Nature       Date:  2021-08-11       Impact factor: 69.504

7.  Loss of KDM4B exacerbates bone-fat imbalance and mesenchymal stromal cell exhaustion in skeletal aging.

Authors:  Peng Deng; Quan Yuan; Yingduan Cheng; Jiong Li; Zhenqing Liu; Yan Liu; Ye Li; Trent Su; Jing Wang; Mari Ekimyan Salvo; Weiguang Wang; Guoping Fan; Karen Lyons; Bo Yu; Cun-Yu Wang
Journal:  Cell Stem Cell       Date:  2021-02-10       Impact factor: 25.269

8.  Articular cartilage regeneration by activated skeletal stem cells.

Authors:  Matthew P Murphy; Lauren S Koepke; Michael T Lopez; Xinming Tong; Thomas H Ambrosi; Gunsagar S Gulati; Owen Marecic; Yuting Wang; Ryan C Ransom; Malachia Y Hoover; Holly Steininger; Liming Zhao; Marcin P Walkiewicz; Natalina Quarto; Benjamin Levi; Derrick C Wan; Irving L Weissman; Stuart B Goodman; Fan Yang; Michael T Longaker; Charles K F Chan
Journal:  Nat Med       Date:  2020-08-17       Impact factor: 53.440

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Authors:  Puneet Agarwal; Hui Li; Kwangmin Choi; Kathleen Hueneman; Jianbo He; Robert S Welner; Daniel T Starczynowski; Ravi Bhatia
Journal:  Cell Rep       Date:  2021-07-13       Impact factor: 9.423

10.  Dissecting human embryonic skeletal stem cell ontogeny by single-cell transcriptomic and functional analyses.

Authors:  Jian He; Jing Yan; Jianfang Wang; Liangyu Zhao; Qian Xin; Yang Zeng; Yuxi Sun; Han Zhang; Zhijie Bai; Zongcheng Li; Yanli Ni; Yandong Gong; Yunqiao Li; Han He; Zhilei Bian; Yu Lan; Chunyu Ma; Lihong Bian; Heng Zhu; Bing Liu; Rui Yue
Journal:  Cell Res       Date:  2021-01-20       Impact factor: 25.617
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