Metabolites (Dec 2023)

Targeting Longevity Gene <i>SLC13A5</i>: A Novel Approach to Prevent Age-Related Bone Fragility and Osteoporosis

  • Grit Zahn,
  • Hannes A. Baukmann,
  • Jasmine Wu,
  • Jens Jordan,
  • Andreas L. Birkenfeld,
  • Naomi Dirckx,
  • Marco F. Schmidt

DOI
https://doi.org/10.3390/metabo13121186
Journal volume & issue
Vol. 13, no. 12
p. 1186

Abstract

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Reduced expression of the plasma membrane citrate transporter SLC13A5, also known as INDY, has been linked to increased longevity and mitigated age-related cardiovascular and metabolic diseases. Citrate, a vital component of the tricarboxylic acid cycle, constitutes 1–5% of bone weight, binding to mineral apatite surfaces. Our previous research highlighted osteoblasts’ specialized metabolic pathway facilitated by SLC13A5 regulating citrate uptake, production, and deposition within bones. Disrupting this pathway impairs bone mineralization in young mice. New Mendelian randomization analysis using UK Biobank data indicated that SNPs linked to reduced SLC13A5 function lowered osteoporosis risk. Comparative studies of young (10 weeks) and middle-aged (52 weeks) osteocalcin-cre-driven osteoblast-specific Slc13a5 knockout mice (Slc13a5cKO) showed a sexual dimorphism: while middle-aged females exhibited improved elasticity, middle-aged males demonstrated enhanced bone strength due to reduced SLC13A5 function. These findings suggest reduced SLC13A5 function could attenuate age-related bone fragility, advocating for SLC13A5 inhibition as a potential osteoporosis treatment.

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