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

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

doi:10.1073/pnas.2212178119

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

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

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

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 Slc13a5^2/2 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.

Original language	English (US)
Article number	e2212178119
Journal	Proceedings of the National Academy of Sciences of the United States of America
Volume	119
Issue number	45
DOIs	https://doi.org/10.1073/pnas.2212178119
State	Published - Nov 8 2022
Externally published	Yes

Keywords

citrate
metabolism
mineralization
osteoblasts
Slc13a5

ASJC Scopus subject areas

General

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10.1073/pnas.2212178119

Cite this

Dirckx, N., Zhang, Q., Chu, E. Y., Tower, R. J., Li, Z., Guo, S., Yuan, S., Khare, P. A., Zhang, C., Verardo, A., Alejandro, L. O., Park, A., Faugere, M. C., Helfand, S. L., Somerman, M. J., Riddle, R. C., de Cabo, R., Le, A., Schmidt-Rohr, K., & Clemens, T. L. (2022). A specialized metabolic pathway partitions citrate in hydroxyapatite to impact mineralization of bones and teeth. Proceedings of the National Academy of Sciences of the United States of America, 119(45), [e2212178119]. https://doi.org/10.1073/pnas.2212178119

Dirckx, N, Zhang, Q, Chu, EY, Tower, RJ, Li, Z, Guo, S, Yuan, S, Khare, PA, Zhang, C, Verardo, A, Alejandro, LO, Park, A, Faugere, MC, Helfand, SL, Somerman, MJ, Riddle, RC, de Cabo, R, Le, A, Schmidt-Rohr, K & Clemens, TL 2022, 'A specialized metabolic pathway partitions citrate in hydroxyapatite to impact mineralization of bones and teeth', Proceedings of the National Academy of Sciences of the United States of America, vol. 119, no. 45, e2212178119. https://doi.org/10.1073/pnas.2212178119

@article{54d2887214a2497f90ad7ad408b43a07,

title = "A specialized metabolic pathway partitions citrate in hydroxyapatite to impact mineralization of bones and teeth",

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{\textquoteright}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 Slc13a52/2 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.",

keywords = "citrate, metabolism, mineralization, osteoblasts, Slc13a5",

author = "Naomi Dirckx and Qian Zhang and Chu, {Emily Y.} and Tower, {Robert J.} and Zhu Li and Shenghao Guo and Shichen Yuan and Khare, {Pratik A.} and Cissy Zhang and Angela Verardo and Alejandro, {Lucy O.} and Angelina Park and Faugere, {Marie Claude} and Helfand, {Stephen L.} and Somerman, {Martha J.} and Riddle, {Ryan C.} and {de Cabo}, Rafael and Anne Le and Klaus Schmidt-Rohr and Clemens, {Thomas L.}",

note = "Funding Information: We acknowledge Dr. Cathrine Hoyo, Ms. Rachel Maguire, and Dr. Sarah Park for providing control tooth samples (North Carolina State University; Newborn Epigenetics Study funded by NIH Grant R24ES028531 to Dr. Hoyo), the TESS Research Foundation (www.tessresearch. org) for providing the SLC13A5 patient primary teeth, Dr. Aaron James for providing human calvarial osteoblasts, and the NINDS JHU Center for Neuroscience Research, Murine Mutagenesis Core (NIH Grant NS050274) for their support in the generation of the ZIP KO mice. We also acknowledge the National Institute of Dental and Craniofacial Research micro-CT core facility for technical assistance and usage of their micro-CT scanner. We thank Dr. Melinda Duer and Dr. Leslie C. Costello for their constructive advice in the design of these experiments. This work was funded by the National Institute of Arthritis and Musculoskeletal and Skin Diseases (NIAMS) K99/R00 Career Development Award K99AR079558 (to N.D.), the Uplifting Athletes Young Investigator draft funding (to N.D.), NIAMS intramural research program funding (to E.Y.C.), Research Grant R00DE031148-02 (to E.Y.C.), start-up funds from the University of Maryland School of Dentistry (to E.Y.C.), and NIH grant funding 1S10OD025226-01 to A.L. T.L.C. is a recipient of a research career scientist award from the Department of Veterans Affairs (5IK6BX004984-03). The solid-state NMR spectrometer used in this work was funded by the NSF-Major Research Instrumentation program (Award No. 1726346, to K.S.-R.). M.-C.F. was funded by the Kentucky Nephrology Research Fund. R.d.C was funded through the NIA intramural Research Program. Funding Information: ACKNOWLEDGMENTS. We acknowledge Dr. Cathrine Hoyo, Ms. Rachel Maguire, and Dr. Sarah Park for providing control tooth samples (North Carolina State University; Newborn Epigenetics Study funded by NIH Grant R24ES028531 to Dr. Hoyo), the TESS Research Foundation (www.tessresearch. org) for providing the SLC13A5 patient primary teeth, Dr. Aaron James for providing human calvarial osteoblasts, and the NINDS JHU Center for Neuroscience Research, Murine Mutagenesis Core (NIH Grant NS050274) for their support in the generation of the ZIP KO mice. We also acknowledge the National Institute of Dental and Craniofacial Research micro-CT core facility for technical assistance and usage of their micro-CT scanner. We thank Dr. Melinda Duer and Dr. Leslie C. Costello for their constructive advice in the design of these experiments. This work was funded by the National Institute of Arthritis and Musculoskeletal and Skin Diseases (NIAMS) K99/R00 Career Development Award K99AR079558 (to N.D.), the Uplifting Athletes Young Investigator draft funding (to N.D.), NIAMS intramural research program funding (to E.Y.C.), Research Grant R00DE031148-02 (to E.Y.C.), start-up funds from the University of Maryland School of Dentistry (to E.Y.C.), and NIH grant funding 1S10OD025226-01 to A.L. T.L.C. is a recipient of a research career scientist award from the Department of Veterans Affairs (5IK6BX004984-03). The solid-state NMR spectrometer used in this work was funded by the NSF-Major Research Instrumentation program (Award No. 1726346, to K.S.-R.). M.-C.F. was funded by the Kentucky Nephrology Research Fund. R.d.C was funded through the NIA intramural Research Program. Funding Information: Dr. Sarah Park (North Carolina State University; Newborn Epigenetics Study funded by R24ES028531 to Cathrine Hoyo) and the TESS Research Foundation (www.tessresearch.org). The full study using control and patient teeth was approved by the local institutional review board at Johns Hopkins University (IRB00268540). Informed consent was obtained from all of the subjects. Publisher Copyright: Copyright {\textcopyright} 2022 the Author(s).",

year = "2022",

month = nov,

day = "8",

doi = "10.1073/pnas.2212178119",

language = "English (US)",

volume = "119",

journal = "Proceedings of the National Academy of Sciences of the United States of America",

issn = "0027-8424",

publisher = "National Academy of Sciences",

number = "45",

}

TY - JOUR

T1 - A specialized metabolic pathway partitions citrate in hydroxyapatite to impact mineralization of bones and teeth

AU - Dirckx, Naomi

AU - Zhang, Qian

AU - Chu, Emily Y.

AU - Tower, Robert J.

AU - Li, Zhu

AU - Guo, Shenghao

AU - Yuan, Shichen

AU - Khare, Pratik A.

AU - Zhang, Cissy

AU - Verardo, Angela

AU - Alejandro, Lucy O.

AU - Park, Angelina

AU - Faugere, Marie Claude

AU - Helfand, Stephen L.

AU - Somerman, Martha J.

AU - Riddle, Ryan C.

AU - de Cabo, Rafael

AU - Le, Anne

AU - Schmidt-Rohr, Klaus

AU - Clemens, Thomas L.

N1 - Funding Information: We acknowledge Dr. Cathrine Hoyo, Ms. Rachel Maguire, and Dr. Sarah Park for providing control tooth samples (North Carolina State University; Newborn Epigenetics Study funded by NIH Grant R24ES028531 to Dr. Hoyo), the TESS Research Foundation (www.tessresearch. org) for providing the SLC13A5 patient primary teeth, Dr. Aaron James for providing human calvarial osteoblasts, and the NINDS JHU Center for Neuroscience Research, Murine Mutagenesis Core (NIH Grant NS050274) for their support in the generation of the ZIP KO mice. We also acknowledge the National Institute of Dental and Craniofacial Research micro-CT core facility for technical assistance and usage of their micro-CT scanner. We thank Dr. Melinda Duer and Dr. Leslie C. Costello for their constructive advice in the design of these experiments. This work was funded by the National Institute of Arthritis and Musculoskeletal and Skin Diseases (NIAMS) K99/R00 Career Development Award K99AR079558 (to N.D.), the Uplifting Athletes Young Investigator draft funding (to N.D.), NIAMS intramural research program funding (to E.Y.C.), Research Grant R00DE031148-02 (to E.Y.C.), start-up funds from the University of Maryland School of Dentistry (to E.Y.C.), and NIH grant funding 1S10OD025226-01 to A.L. T.L.C. is a recipient of a research career scientist award from the Department of Veterans Affairs (5IK6BX004984-03). The solid-state NMR spectrometer used in this work was funded by the NSF-Major Research Instrumentation program (Award No. 1726346, to K.S.-R.). M.-C.F. was funded by the Kentucky Nephrology Research Fund. R.d.C was funded through the NIA intramural Research Program. Funding Information: ACKNOWLEDGMENTS. We acknowledge Dr. Cathrine Hoyo, Ms. Rachel Maguire, and Dr. Sarah Park for providing control tooth samples (North Carolina State University; Newborn Epigenetics Study funded by NIH Grant R24ES028531 to Dr. Hoyo), the TESS Research Foundation (www.tessresearch. org) for providing the SLC13A5 patient primary teeth, Dr. Aaron James for providing human calvarial osteoblasts, and the NINDS JHU Center for Neuroscience Research, Murine Mutagenesis Core (NIH Grant NS050274) for their support in the generation of the ZIP KO mice. We also acknowledge the National Institute of Dental and Craniofacial Research micro-CT core facility for technical assistance and usage of their micro-CT scanner. We thank Dr. Melinda Duer and Dr. Leslie C. Costello for their constructive advice in the design of these experiments. This work was funded by the National Institute of Arthritis and Musculoskeletal and Skin Diseases (NIAMS) K99/R00 Career Development Award K99AR079558 (to N.D.), the Uplifting Athletes Young Investigator draft funding (to N.D.), NIAMS intramural research program funding (to E.Y.C.), Research Grant R00DE031148-02 (to E.Y.C.), start-up funds from the University of Maryland School of Dentistry (to E.Y.C.), and NIH grant funding 1S10OD025226-01 to A.L. T.L.C. is a recipient of a research career scientist award from the Department of Veterans Affairs (5IK6BX004984-03). The solid-state NMR spectrometer used in this work was funded by the NSF-Major Research Instrumentation program (Award No. 1726346, to K.S.-R.). M.-C.F. was funded by the Kentucky Nephrology Research Fund. R.d.C was funded through the NIA intramural Research Program. Funding Information: Dr. Sarah Park (North Carolina State University; Newborn Epigenetics Study funded by R24ES028531 to Cathrine Hoyo) and the TESS Research Foundation (www.tessresearch.org). The full study using control and patient teeth was approved by the local institutional review board at Johns Hopkins University (IRB00268540). Informed consent was obtained from all of the subjects. Publisher Copyright: Copyright © 2022 the Author(s).

PY - 2022/11/8

Y1 - 2022/11/8

N2 - 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 Slc13a52/2 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.

AB - 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 Slc13a52/2 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.

KW - citrate

KW - metabolism

KW - mineralization

KW - osteoblasts

KW - Slc13a5

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U2 - 10.1073/pnas.2212178119

DO - 10.1073/pnas.2212178119

M3 - Article

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SN - 0027-8424

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JO - Proceedings of the National Academy of Sciences of the United States of America

JF - Proceedings of the National Academy of Sciences of the United States of America

IS - 45

M1 - e2212178119

ER -

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

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