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A specialized metabolic pathway partitions citrate in hydroxyapatite to impact mineralization of bones and teeth

Authors :
Naomi Dirckx
Qian Zhang
Emily Y. Chu
Robert J. Tower
Zhu Li
Shenghao Guo
Shichen Yuan
Pratik A. Khare
Cissy Zhang
Angela Verardo
Lucy O. Alejandro
Angelina Park
Marie-Claude Faugere
Stephen L. Helfand
Martha J. Somerman
Ryan C. Riddle
Rafael de Cabo
Anne Le
Klaus Schmidt-Rohr
Thomas L. Clemens
Source :
Proceedings of the National Academy of Sciences. 119
Publication Year :
2022
Publisher :
Proceedings of the National Academy of Sciences, 2022.

Abstract

Citrate is a critical metabolic substrate and key regulator of energy metabolism in mammalian cells. It has been known for decades that the skeleton contains most (>85%) of the body’s citrate, but the question of why and how this metabolite should be partitioned in bone has received singularly little attention. Here, we show that osteoblasts use a specialized metabolic pathway to regulate uptake, endogenous production, and the deposition of citrate into bone. Osteoblasts express high levels of the membranous Na + -dependent citrate transporter solute carrier family 13 member 5 ( Slc13a5 ) gene. Inhibition or genetic disruption of Slc13a5 reduced osteogenic citrate uptake and disrupted mineral nodule formation. Bones from mice lacking Slc13a5 globally, or selectively in osteoblasts, showed equivalent reductions in cortical thickness, with similarly compromised mechanical strength. Surprisingly, citrate content in mineral from Slc13a5 −/− osteoblasts was increased fourfold relative to controls, suggesting the engagement of compensatory mechanisms to augment endogenous citrate production. Indeed, through the coordinated functioning of the apical membrane citrate transporter SLC13A5 and a mitochondrial zinc transporter protein (ZIP1; encoded by Slc39a1 ), a mediator of citrate efflux from the tricarboxylic acid cycle, SLC13A5 mediates citrate entry from blood and its activity exerts homeostatic control of cytoplasmic citrate. Intriguingly, Slc13a5 -deficient mice also exhibited defective tooth enamel and dentin formation, a clinical feature, which we show is recapitulated in primary teeth from children with SLC13A5 mutations. Together, our results reveal the components of an osteoblast metabolic pathway, which affects bone strength by regulating citrate deposition into mineral hydroxyapatite.

Details

ISSN :
10916490 and 00278424
Volume :
119
Database :
OpenAIRE
Journal :
Proceedings of the National Academy of Sciences
Accession number :
edsair.doi.dedup.....f4ab23654675892566107ebde1b8233f
Full Text :
https://doi.org/10.1073/pnas.2212178119