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A tissue-bioengineering strategy for modeling rare human kidney diseases in vivo

Author

Listed:
  • J. O. R. Hernandez

    (Brigham and Women’s Hospital)

  • X. Wang

    (Brigham and Women’s Hospital)

  • M. Vazquez-Segoviano

    (Brigham and Women’s Hospital)

  • M. Lopez-Marfil

    (Brigham and Women’s Hospital)

  • M. F. Sobral-Reyes

    (Brigham and Women’s Hospital)

  • A. Moran-Horowich

    (Brigham and Women’s Hospital)

  • M. Sundberg

    (Boston Children’s Hospital
    Harvard Medical School)

  • D. O. Lopez-Cantu

    (Brigham and Women’s Hospital)

  • C. K. Probst

    (Brigham and Women’s Hospital
    Brigham and Women’s Hospital)

  • G. U. Ruiz-Esparza

    (Brigham and Women’s Hospital)

  • K. Giannikou

    (Harvard Medical School
    Brigham and Women’s Hospital
    Brigham and Women’s Hospital)

  • R. Abdi

    (Harvard Medical School)

  • E. P. Henske

    (Harvard Medical School
    Brigham and Women’s Hospital
    Brigham and Women’s Hospital)

  • D. J. Kwiatkowski

    (Harvard Medical School
    Brigham and Women’s Hospital
    Brigham and Women’s Hospital)

  • M. Sahin

    (Boston Children’s Hospital
    Harvard Medical School)

  • D. R. Lemos

    (Brigham and Women’s Hospital
    Harvard Medical School
    Harvard Stem Cell Institute)

Abstract

The lack of animal models for some human diseases precludes our understanding of disease mechanisms and our ability to test prospective therapies in vivo. Generation of kidney organoids from Tuberous Sclerosis Complex (TSC) patient-derived-hiPSCs allows us to recapitulate a rare kidney tumor called angiomyolipoma (AML). Organoids derived from TSC2−/− hiPSCs but not from isogenic TSC2+/− or TSC2+/+ hiPSCs share a common transcriptional signature and a myomelanocytic cell phenotype with kidney AMLs, and develop epithelial cysts, replicating two major TSC-associated kidney lesions driven by genetic mechanisms that cannot be consistently recapitulated with transgenic mice. Transplantation of multiple TSC2−/− renal organoids into the kidneys of immunodeficient rats allows us to model AML in vivo for the study of tumor mechanisms, and to test the efficacy of rapamycin-loaded nanoparticles as an approach to rapidly ablate AMLs. Collectively, our experimental approaches represent an innovative and scalable tissue-bioengineering strategy for modeling rare kidney disease in vivo.

Suggested Citation

  • J. O. R. Hernandez & X. Wang & M. Vazquez-Segoviano & M. Lopez-Marfil & M. F. Sobral-Reyes & A. Moran-Horowich & M. Sundberg & D. O. Lopez-Cantu & C. K. Probst & G. U. Ruiz-Esparza & K. Giannikou & R., 2021. "A tissue-bioengineering strategy for modeling rare human kidney diseases in vivo," Nature Communications, Nature, vol. 12(1), pages 1-16, December.
    • Handle: RePEc:nat:natcom:v:12:y:2021:i:1:d:10.1038_s41467-021-26596-y
    DOI: 10.1038/s41467-021-26596-y
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    1. Benjamin S. Freedman & Craig R. Brooks & Albert Q. Lam & Hongxia Fu & Ryuji Morizane & Vishesh Agrawal & Abdelaziz F. Saad & Michelle K. Li & Michael R. Hughes & Ryan Vander Werff & Derek T. Peters & , 2015. "Modelling kidney disease with CRISPR-mutant kidney organoids derived from human pluripotent epiblast spheroids," Nature Communications, Nature, vol. 6(1), pages 1-13, December.
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