Superstable lipid vacuoles endow cartilage with its shape and biomechanics

Raul Ramos; Kim T. Pham; Richard C. Prince; Leith B. Leiser-Miller; Maneeshi S. Prasad; Xiaojie Wang; Rachel C. Nordberg; Benjamin J. Bielajew; Jerry C. Hu; Kosuke Yamaga; Ji Won Oh; Tao Peng; Rupsa Datta; Aksana Astrowskaja; Axel A. Almet; John T. Burns; Yuchen Liu; Christian Fernando Guerrero-Juarez; Bryant Q. Tran; Yi Lin Chu; Anh M. Nguyen; Tsai Ching Hsi; Norman T.L. Lim; Sandra Schoeniger; Ruiqi Liu; Yun Ling Pai; Chella K. Vadivel; Sandy Ingleby; Andrew E. McKechnie; Frank van Breukelen; Kyle L. Hoehn; John J. Rasweiler; Michinori Kohara; William J. Loughry; Scott H. Weldy; Raymond Cosper; Chao Chun Yang; Sung Jan Lin; Kimberly L. Cooper; Sharlene E. Santana; Jeffrey E. Bradley; Michael A. Kiebish; Michelle Digman; David E. James; Amy E. Merrill; Qing Nie; Thomas F. Schilling; Aliaksandr A. Astrowski; Eric O. Potma; Martín I. García-Castro; Kyriacos A. Athanasiou; Richard R. Behringer; Maksim V. Plikus

doi:10.1126/science.ads9960

Superstable lipid vacuoles endow cartilage with its shape and biomechanics

Raul Ramos
, Kim T. Pham
, Richard C. Prince
, Leith B. Leiser-Miller
, Maneeshi S. Prasad
, Xiaojie Wang
, Rachel C. Nordberg
, Benjamin J. Bielajew
, Jerry C. Hu
, Kosuke Yamaga
, Ji Won Oh
, Tao Peng
, Rupsa Datta
, Aksana Astrowskaja
, Axel A. Almet
, John T. Burns
, Yuchen Liu
, Christian Fernando Guerrero-Juarez
, Bryant Q. Tran
, Yi Lin Chu

Anh M. Nguyen, Tsai Ching Hsi, Norman T.L. Lim, Sandra Schoeniger, Ruiqi Liu, Yun Ling Pai, Chella K. Vadivel, Sandy Ingleby, Andrew E. McKechnie, Frank van Breukelen, Kyle L. Hoehn, John J. Rasweiler, Michinori Kohara, William J. Loughry, Scott H. Weldy, Raymond Cosper, Chao Chun Yang, Sung Jan Lin, Kimberly L. Cooper, Sharlene E. Santana, Jeffrey E. Bradley, Michael A. Kiebish, Michelle Digman, David E. James, Amy E. Merrill, Qing Nie, Thomas F. Schilling, Aliaksandr A. Astrowski, Eric O. Potma, Martín I. García-Castro, Kyriacos A. Athanasiou, Richard R. Behringer, Maksim V. Plikus

Biochemistry

University of California at Irvine
University of Washington
Yonsei University
Kyungpook National University
Grodna State Medical University
Nanyang Technological University
Leipzig University
Discovery Life Sciences Biomarker Services GmbH
National Taiwan University
University of Copenhagen
Australian Museum
University of Pretoria
South African National Biodiversity Institute
University of Nevada, Las Vegas
University of New South Wales
SUNY Downstate Health Sciences University
Tokyo Metropolitan Institute of Medical Science
Valdosta State University
Serrano Animal and Bird Hospital
Santa Ana Zoo
National Cheng Kung University
University of California at San Diego
BPGbio, Inc.
The University of Sydney
University of Southern California
Belarus Academy of Sciences
University of California at Riverside
University of Texas MD Anderson Cancer Center

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

16 Scopus citations

Abstract

Conventionally, the size, shape, and biomechanics of cartilages are determined by their voluminous extracellular matrix. By contrast, we found that multiple murine cartilages consist of lipid-filled cells called lipochondrocytes. Despite resembling adipocytes, lipochondrocytes were molecularly distinct and produced lipids exclusively through de novo lipogenesis. Consequently, lipochondrocytes grew uniform lipid droplets that resisted systemic lipid surges and did not enlarge upon obesity. Lipochondrocytes also lacked lipid mobilization factors, which enabled exceptional vacuole stability and protected cartilage from shrinking upon starvation. Lipid droplets modulated lipocartilage biomechanics by decreasing the tissue’s stiffness, strength, and resilience. Lipochondrocytes were found in multiple mammals, including humans, but not in nonmammalian tetrapods. Thus, analogous to bubble wrap, superstable lipid vacuoles confer skeletal tissue with cartilage-like properties without “packing foam–like” extracellular matrix.

Original language	English
Article number	eads9960
Journal	Science
Volume	387
Issue number	6730
DOIs	https://doi.org/10.1126/science.ads9960
State	Published - Jan 10 2025

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10.1126/science.ads9960

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Ramos, R., Pham, K. T., Prince, R. C., Leiser-Miller, L. B., Prasad, M. S., Wang, X., Nordberg, R. C., Bielajew, B. J., Hu, J. C., Yamaga, K., Oh, J. W., Peng, T., Datta, R., Astrowskaja, A., Almet, A. A., Burns, J. T., Liu, Y., Guerrero-Juarez, C. F., Tran, B. Q., ... Plikus, M. V. (2025). Superstable lipid vacuoles endow cartilage with its shape and biomechanics. Science, 387(6730), Article eads9960. https://doi.org/10.1126/science.ads9960

@article{0a825fb025194fe0af0deab837876ee5,

title = "Superstable lipid vacuoles endow cartilage with its shape and biomechanics",

abstract = "Conventionally, the size, shape, and biomechanics of cartilages are determined by their voluminous extracellular matrix. By contrast, we found that multiple murine cartilages consist of lipid-filled cells called lipochondrocytes. Despite resembling adipocytes, lipochondrocytes were molecularly distinct and produced lipids exclusively through de novo lipogenesis. Consequently, lipochondrocytes grew uniform lipid droplets that resisted systemic lipid surges and did not enlarge upon obesity. Lipochondrocytes also lacked lipid mobilization factors, which enabled exceptional vacuole stability and protected cartilage from shrinking upon starvation. Lipid droplets modulated lipocartilage biomechanics by decreasing the tissue{\textquoteright}s stiffness, strength, and resilience. Lipochondrocytes were found in multiple mammals, including humans, but not in nonmammalian tetrapods. Thus, analogous to bubble wrap, superstable lipid vacuoles confer skeletal tissue with cartilage-like properties without “packing foam–like” extracellular matrix.",

author = "Raul Ramos and Pham, \{Kim T.\} and Prince, \{Richard C.\} and Leiser-Miller, \{Leith B.\} and Prasad, \{Maneeshi S.\} and Xiaojie Wang and Nordberg, \{Rachel C.\} and Bielajew, \{Benjamin J.\} and Hu, \{Jerry C.\} and Kosuke Yamaga and Oh, \{Ji Won\} and Tao Peng and Rupsa Datta and Aksana Astrowskaja and Almet, \{Axel A.\} and Burns, \{John T.\} and Yuchen Liu and Guerrero-Juarez, \{Christian Fernando\} and Tran, \{Bryant Q.\} and Chu, \{Yi Lin\} and Nguyen, \{Anh M.\} and Hsi, \{Tsai Ching\} and Lim, \{Norman T.L.\} and Sandra Schoeniger and Ruiqi Liu and Pai, \{Yun Ling\} and Vadivel, \{Chella K.\} and Sandy Ingleby and McKechnie, \{Andrew E.\} and \{van Breukelen\}, Frank and Hoehn, \{Kyle L.\} and Rasweiler, \{John J.\} and Michinori Kohara and Loughry, \{William J.\} and Weldy, \{Scott H.\} and Raymond Cosper and Yang, \{Chao Chun\} and Lin, \{Sung Jan\} and Cooper, \{Kimberly L.\} and Santana, \{Sharlene E.\} and Bradley, \{Jeffrey E.\} and Kiebish, \{Michael A.\} and Michelle Digman and James, \{David E.\} and Merrill, \{Amy E.\} and Qing Nie and Schilling, \{Thomas F.\} and Astrowski, \{Aliaksandr A.\} and Potma, \{Eric O.\} and Garc{\'i}a-Castro, \{Mart{\'i}n I.\} and Athanasiou, \{Kyriacos A.\} and Behringer, \{Richard R.\} and Plikus, \{Maksim V.\}",

year = "2025",

month = jan,

day = "10",

doi = "10.1126/science.ads9960",

language = "English",

volume = "387",

journal = "Science",

issn = "0036-8075",

publisher = "American Association for the Advancement of Science",

number = "6730",

}

Ramos, R, Pham, KT, Prince, RC, Leiser-Miller, LB, Prasad, MS, Wang, X, Nordberg, RC, Bielajew, BJ, Hu, JC, Yamaga, K, Oh, JW, Peng, T, Datta, R, Astrowskaja, A, Almet, AA, Burns, JT, Liu, Y, Guerrero-Juarez, CF, Tran, BQ, Chu, YL, Nguyen, AM, Hsi, TC, Lim, NTL, Schoeniger, S, Liu, R, Pai, YL, Vadivel, CK, Ingleby, S, McKechnie, AE, van Breukelen, F, Hoehn, KL, Rasweiler, JJ, Kohara, M, Loughry, WJ, Weldy, SH, Cosper, R, Yang, CC, Lin, SJ, Cooper, KL, Santana, SE, Bradley, JE, Kiebish, MA, Digman, M, James, DE, Merrill, AE, Nie, Q, Schilling, TF, Astrowski, AA, Potma, EO, García-Castro, MI, Athanasiou, KA, Behringer, RR & Plikus, MV 2025, 'Superstable lipid vacuoles endow cartilage with its shape and biomechanics', Science, vol. 387, no. 6730, eads9960. https://doi.org/10.1126/science.ads9960

TY - JOUR

T1 - Superstable lipid vacuoles endow cartilage with its shape and biomechanics

AU - Ramos, Raul

AU - Pham, Kim T.

AU - Prince, Richard C.

AU - Leiser-Miller, Leith B.

AU - Prasad, Maneeshi S.

AU - Wang, Xiaojie

AU - Nordberg, Rachel C.

AU - Bielajew, Benjamin J.

AU - Hu, Jerry C.

AU - Yamaga, Kosuke

AU - Oh, Ji Won

AU - Peng, Tao

AU - Datta, Rupsa

AU - Astrowskaja, Aksana

AU - Almet, Axel A.

AU - Burns, John T.

AU - Liu, Yuchen

AU - Guerrero-Juarez, Christian Fernando

AU - Tran, Bryant Q.

AU - Chu, Yi Lin

AU - Nguyen, Anh M.

AU - Hsi, Tsai Ching

AU - Lim, Norman T.L.

AU - Schoeniger, Sandra

AU - Liu, Ruiqi

AU - Pai, Yun Ling

AU - Vadivel, Chella K.

AU - Ingleby, Sandy

AU - McKechnie, Andrew E.

AU - van Breukelen, Frank

AU - Hoehn, Kyle L.

AU - Rasweiler, John J.

AU - Kohara, Michinori

AU - Loughry, William J.

AU - Weldy, Scott H.

AU - Cosper, Raymond

AU - Yang, Chao Chun

AU - Lin, Sung Jan

AU - Cooper, Kimberly L.

AU - Santana, Sharlene E.

AU - Bradley, Jeffrey E.

AU - Kiebish, Michael A.

AU - Digman, Michelle

AU - James, David E.

AU - Merrill, Amy E.

AU - Nie, Qing

AU - Schilling, Thomas F.

AU - Astrowski, Aliaksandr A.

AU - Potma, Eric O.

AU - García-Castro, Martín I.

AU - Athanasiou, Kyriacos A.

AU - Behringer, Richard R.

AU - Plikus, Maksim V.

PY - 2025/1/10

Y1 - 2025/1/10

N2 - Conventionally, the size, shape, and biomechanics of cartilages are determined by their voluminous extracellular matrix. By contrast, we found that multiple murine cartilages consist of lipid-filled cells called lipochondrocytes. Despite resembling adipocytes, lipochondrocytes were molecularly distinct and produced lipids exclusively through de novo lipogenesis. Consequently, lipochondrocytes grew uniform lipid droplets that resisted systemic lipid surges and did not enlarge upon obesity. Lipochondrocytes also lacked lipid mobilization factors, which enabled exceptional vacuole stability and protected cartilage from shrinking upon starvation. Lipid droplets modulated lipocartilage biomechanics by decreasing the tissue’s stiffness, strength, and resilience. Lipochondrocytes were found in multiple mammals, including humans, but not in nonmammalian tetrapods. Thus, analogous to bubble wrap, superstable lipid vacuoles confer skeletal tissue with cartilage-like properties without “packing foam–like” extracellular matrix.

AB - Conventionally, the size, shape, and biomechanics of cartilages are determined by their voluminous extracellular matrix. By contrast, we found that multiple murine cartilages consist of lipid-filled cells called lipochondrocytes. Despite resembling adipocytes, lipochondrocytes were molecularly distinct and produced lipids exclusively through de novo lipogenesis. Consequently, lipochondrocytes grew uniform lipid droplets that resisted systemic lipid surges and did not enlarge upon obesity. Lipochondrocytes also lacked lipid mobilization factors, which enabled exceptional vacuole stability and protected cartilage from shrinking upon starvation. Lipid droplets modulated lipocartilage biomechanics by decreasing the tissue’s stiffness, strength, and resilience. Lipochondrocytes were found in multiple mammals, including humans, but not in nonmammalian tetrapods. Thus, analogous to bubble wrap, superstable lipid vacuoles confer skeletal tissue with cartilage-like properties without “packing foam–like” extracellular matrix.

UR - https://www.scopus.com/pages/publications/85214934891

U2 - 10.1126/science.ads9960

DO - 10.1126/science.ads9960

M3 - Article

C2 - 39787221

AN - SCOPUS:85214934891

SN - 0036-8075

VL - 387

JO - Science

JF - Science

IS - 6730

M1 - eads9960

ER -

Superstable lipid vacuoles endow cartilage with its shape and biomechanics

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