Nature Communications (Jun 2023)

Embryonic vitamin D deficiency programs hematopoietic stem cells to induce type 2 diabetes

  • Jisu Oh,
  • Amy E. Riek,
  • Kevin T. Bauerle,
  • Adriana Dusso,
  • Kyle P. McNerney,
  • Ruteja A. Barve,
  • Isra Darwech,
  • Jennifer E. Sprague,
  • Clare Moynihan,
  • Rong M. Zhang,
  • Greta Kutz,
  • Ting Wang,
  • Xiaoyun Xing,
  • Daofeng Li,
  • Marguerite Mrad,
  • Nicholas M. Wigge,
  • Esmeralda Castelblanco,
  • Alejandro Collin,
  • Monika Bambouskova,
  • Richard D. Head,
  • Mark S. Sands,
  • Carlos Bernal-Mizrachi

DOI
https://doi.org/10.1038/s41467-023-38849-z
Journal volume & issue
Vol. 14, no. 1
pp. 1 – 18

Abstract

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Abstract Environmental factors may alter the fetal genome to cause metabolic diseases. It is unknown whether embryonic immune cell programming impacts the risk of type 2 diabetes in later life. We demonstrate that transplantation of fetal hematopoietic stem cells (HSCs) made vitamin D deficient in utero induce diabetes in vitamin D-sufficient mice. Vitamin D deficiency epigenetically suppresses Jarid2 expression and activates the Mef2/PGC1a pathway in HSCs, which persists in recipient bone marrow, resulting in adipose macrophage infiltration. These macrophages secrete miR106-5p, which promotes adipose insulin resistance by repressing PIK3 catalytic and regulatory subunits and down-regulating AKT signaling. Vitamin D-deficient monocytes from human cord blood have comparable Jarid2/Mef2/PGC1a expression changes and secrete miR-106b-5p, causing adipocyte insulin resistance. These findings suggest that vitamin D deficiency during development has epigenetic consequences impacting the systemic metabolic milieu.