Modularity-based mathematical modeling of ligand inter-nanocluster connectivity for unraveling reversible stem cell regulation

Chowon Kim; Nayeon Kang; Sunhong Min; Ramar Thangam; Sungkyu Lee; Hyunsik Hong; Kanghyeon Kim; Seong Yeol Kim; Dahee Kim; Hyunji Rha; Kyong Ryol Tag; Hyun Jeong Lee; Nem Singh; Daun Jeong; Jangsun Hwang; Yuri Kim; Sangwoo Park; Hyesung Lee; Taeeon Kim; Sang Wook Son; Steve Park; Solmaz Karamikamkar; Yangzhi Zhu; Alireza Hassani Najafabadi; Zhiqin Chu; Wujin Sun; Pengchao Zhao; Kunyu Zhang; Liming Bian; Hyun Cheol Song; Sung Gyu Park; Jong Seung Kim; Sang Yup Lee; Jae Pyoung Ahn; Hong Kyu Kim; Yu Shrike Zhang; Heemin Kang

doi:10.1038/s41467-024-54557-8

Modularity-based mathematical modeling of ligand inter-nanocluster connectivity for unraveling reversible stem cell regulation

Chowon Kim
, Nayeon Kang
, Sunhong Min
, Ramar Thangam
, Sungkyu Lee
, Hyunsik Hong
, Kanghyeon Kim
, Seong Yeol Kim
, Dahee Kim
, Hyunji Rha
, Kyong Ryol Tag
, Hyun Jeong Lee
, Nem Singh
, Daun Jeong
, Jangsun Hwang
, Yuri Kim
, Sangwoo Park
, Hyesung Lee
, Taeeon Kim
, Sang Wook Son

Steve Park, Solmaz Karamikamkar, Yangzhi Zhu, Alireza Hassani Najafabadi, Zhiqin Chu, Wujin Sun, Pengchao Zhao, Kunyu Zhang, Liming Bian, Hyun Cheol Song, Sung Gyu Park, Jong Seung Kim, Sang Yup Lee, Jae Pyoung Ahn, Hong Kyu Kim, Yu Shrike Zhang^*, Heemin Kang^*

^*Corresponding author for this work

Research output: Contribution to journal › Article › peer-review

20 Citations (Scopus)

Abstract

The native extracellular matrix is continuously remodeled to form complex interconnected network structures that reversibly regulate stem cell behaviors. Both regulation and understanding of its intricate dynamicity can help to modulate numerous cell behaviors. However, neither of these has yet been achieved due to the lack of designing and modeling such complex structures with dynamic controllability. Here we report modularity-based mathematical modeling of extracellular matrix-emulating ligand inter-cluster connectivity using the graph theory. Increasing anisotropy of magnetic nano-blockers proportionately disconnects arginine-glycine-aspartic acid ligand-to-ligand interconnections and decreases the number of ligand inter-cluster edges. This phenomenon deactivates stem cells, which can be partly activated by linearizing the nano-blockers. Remote cyclic elevation of high-anisotropy nano-blockers flexibly generates nano-gaps under the nano-blockers and augments the number of ligand inter-cluster edges. Subsequently, integrin-presenting stem cell infiltration is stimulated, which reversibly intensifies focal adhesion and mechanotransduction-driven differentiation both in vitro and in vivo. Designing and systemically modeling extracellular matrix-mimetic geometries opens avenues for unraveling dynamic cell-material interactions for tissue regeneration.

Original language	English
Article number	10665
Journal	Nature communications
Volume	15
Issue number	1
DOIs	https://doi.org/10.1038/s41467-024-54557-8
Publication status	Published - 2024 Dec

Bibliographical note

Publisher Copyright:
© The Author(s) 2024.

ASJC Scopus subject areas

General Chemistry
General Biochemistry,Genetics and Molecular Biology
General
General Physics and Astronomy

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10.1038/s41467-024-54557-8

Cite this

Kim, C., Kang, N., Min, S., Thangam, R., Lee, S., Hong, H., Kim, K., Kim, S. Y., Kim, D., Rha, H., Tag, K. R., Lee, H. J., Singh, N., Jeong, D., Hwang, J., Kim, Y., Park, S., Lee, H., Kim, T., ... Kang, H. (2024). Modularity-based mathematical modeling of ligand inter-nanocluster connectivity for unraveling reversible stem cell regulation. Nature communications, 15(1), Article 10665. https://doi.org/10.1038/s41467-024-54557-8

Kim, C, Kang, N, Min, S, Thangam, R, Lee, S, Hong, H, Kim, K, Kim, SY, Kim, D, Rha, H, Tag, KR, Lee, HJ, Singh, N, Jeong, D, Hwang, J, Kim, Y, Park, S, Lee, H, Kim, T, Son, SW, Park, S, Karamikamkar, S, Zhu, Y, Hassani Najafabadi, A, Chu, Z, Sun, W, Zhao, P, Zhang, K, Bian, L, Song, HC, Park, SG, Kim, JS, Lee, SY, Ahn, JP, Kim, HK, Zhang, YS & Kang, H 2024, 'Modularity-based mathematical modeling of ligand inter-nanocluster connectivity for unraveling reversible stem cell regulation', Nature communications, vol. 15, no. 1, 10665. https://doi.org/10.1038/s41467-024-54557-8

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title = "Modularity-based mathematical modeling of ligand inter-nanocluster connectivity for unraveling reversible stem cell regulation",

abstract = "The native extracellular matrix is continuously remodeled to form complex interconnected network structures that reversibly regulate stem cell behaviors. Both regulation and understanding of its intricate dynamicity can help to modulate numerous cell behaviors. However, neither of these has yet been achieved due to the lack of designing and modeling such complex structures with dynamic controllability. Here we report modularity-based mathematical modeling of extracellular matrix-emulating ligand inter-cluster connectivity using the graph theory. Increasing anisotropy of magnetic nano-blockers proportionately disconnects arginine-glycine-aspartic acid ligand-to-ligand interconnections and decreases the number of ligand inter-cluster edges. This phenomenon deactivates stem cells, which can be partly activated by linearizing the nano-blockers. Remote cyclic elevation of high-anisotropy nano-blockers flexibly generates nano-gaps under the nano-blockers and augments the number of ligand inter-cluster edges. Subsequently, integrin-presenting stem cell infiltration is stimulated, which reversibly intensifies focal adhesion and mechanotransduction-driven differentiation both in vitro and in vivo. Designing and systemically modeling extracellular matrix-mimetic geometries opens avenues for unraveling dynamic cell-material interactions for tissue regeneration.",

author = "Chowon Kim and Nayeon Kang and Sunhong Min and Ramar Thangam and Sungkyu Lee and Hyunsik Hong and Kanghyeon Kim and Kim, \{Seong Yeol\} and Dahee Kim and Hyunji Rha and Tag, \{Kyong Ryol\} and Lee, \{Hyun Jeong\} and Nem Singh and Daun Jeong and Jangsun Hwang and Yuri Kim and Sangwoo Park and Hyesung Lee and Taeeon Kim and Son, \{Sang Wook\} and Steve Park and Solmaz Karamikamkar and Yangzhi Zhu and \{Hassani Najafabadi\}, Alireza and Zhiqin Chu and Wujin Sun and Pengchao Zhao and Kunyu Zhang and Liming Bian and Song, \{Hyun Cheol\} and Park, \{Sung Gyu\} and Kim, \{Jong Seung\} and Lee, \{Sang Yup\} and Ahn, \{Jae Pyoung\} and Kim, \{Hong Kyu\} and Zhang, \{Yu Shrike\} and Heemin Kang",

note = "Publisher Copyright: {\textcopyright} The Author(s) 2024.",

year = "2024",

month = dec,

doi = "10.1038/s41467-024-54557-8",

language = "English",

volume = "15",

journal = "Nature communications",

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AU - Kim, Chowon

AU - Kang, Nayeon

AU - Min, Sunhong

AU - Thangam, Ramar

AU - Lee, Sungkyu

AU - Hong, Hyunsik

AU - Kim, Kanghyeon

AU - Kim, Seong Yeol

AU - Kim, Dahee

AU - Rha, Hyunji

AU - Tag, Kyong Ryol

AU - Lee, Hyun Jeong

AU - Singh, Nem

AU - Jeong, Daun

AU - Hwang, Jangsun

AU - Kim, Yuri

AU - Park, Sangwoo

AU - Lee, Hyesung

AU - Kim, Taeeon

AU - Son, Sang Wook

AU - Park, Steve

AU - Karamikamkar, Solmaz

AU - Zhu, Yangzhi

AU - Hassani Najafabadi, Alireza

AU - Chu, Zhiqin

AU - Sun, Wujin

AU - Zhao, Pengchao

AU - Zhang, Kunyu

AU - Bian, Liming

AU - Song, Hyun Cheol

AU - Park, Sung Gyu

AU - Kim, Jong Seung

AU - Lee, Sang Yup

AU - Ahn, Jae Pyoung

AU - Kim, Hong Kyu

AU - Zhang, Yu Shrike

AU - Kang, Heemin

PY - 2024/12

Y1 - 2024/12

N2 - The native extracellular matrix is continuously remodeled to form complex interconnected network structures that reversibly regulate stem cell behaviors. Both regulation and understanding of its intricate dynamicity can help to modulate numerous cell behaviors. However, neither of these has yet been achieved due to the lack of designing and modeling such complex structures with dynamic controllability. Here we report modularity-based mathematical modeling of extracellular matrix-emulating ligand inter-cluster connectivity using the graph theory. Increasing anisotropy of magnetic nano-blockers proportionately disconnects arginine-glycine-aspartic acid ligand-to-ligand interconnections and decreases the number of ligand inter-cluster edges. This phenomenon deactivates stem cells, which can be partly activated by linearizing the nano-blockers. Remote cyclic elevation of high-anisotropy nano-blockers flexibly generates nano-gaps under the nano-blockers and augments the number of ligand inter-cluster edges. Subsequently, integrin-presenting stem cell infiltration is stimulated, which reversibly intensifies focal adhesion and mechanotransduction-driven differentiation both in vitro and in vivo. Designing and systemically modeling extracellular matrix-mimetic geometries opens avenues for unraveling dynamic cell-material interactions for tissue regeneration.

AB - The native extracellular matrix is continuously remodeled to form complex interconnected network structures that reversibly regulate stem cell behaviors. Both regulation and understanding of its intricate dynamicity can help to modulate numerous cell behaviors. However, neither of these has yet been achieved due to the lack of designing and modeling such complex structures with dynamic controllability. Here we report modularity-based mathematical modeling of extracellular matrix-emulating ligand inter-cluster connectivity using the graph theory. Increasing anisotropy of magnetic nano-blockers proportionately disconnects arginine-glycine-aspartic acid ligand-to-ligand interconnections and decreases the number of ligand inter-cluster edges. This phenomenon deactivates stem cells, which can be partly activated by linearizing the nano-blockers. Remote cyclic elevation of high-anisotropy nano-blockers flexibly generates nano-gaps under the nano-blockers and augments the number of ligand inter-cluster edges. Subsequently, integrin-presenting stem cell infiltration is stimulated, which reversibly intensifies focal adhesion and mechanotransduction-driven differentiation both in vitro and in vivo. Designing and systemically modeling extracellular matrix-mimetic geometries opens avenues for unraveling dynamic cell-material interactions for tissue regeneration.

UR - https://www.scopus.com/pages/publications/85212785061

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C2 - 39715783

AN - SCOPUS:85212785061

SN - 2041-1723

VL - 15

JO - Nature communications

JF - Nature communications

IS - 1

M1 - 10665

ER -

Modularity-based mathematical modeling of ligand inter-nanocluster connectivity for unraveling reversible stem cell regulation

Abstract

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ASJC Scopus subject areas

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