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01-12-2021 | Research article

Lactate oxidative phosphorylation by annulus fibrosus cells: evidence for lactate-dependent metabolic symbiosis in intervertebral discs

Authors: Dong Wang, Robert Hartman, Chao Han, Chao-ming Zhou, Brandon Couch, Matias Malkamaki, Vera Roginskaya, Bennett Van Houten, Steven J. Mullett, Stacy G. Wendell, Michael J. Jurczak, James Kang, Joon Lee, Gwendolyn Sowa, Nam Vo

Published in: Arthritis Research & Therapy | Issue 1/2021

Abstract

Background

Intervertebral disc degeneration contributes to low back pain. The avascular intervertebral disc consists of a central hypoxic nucleus pulpous (NP) surrounded by the more oxygenated annulus fibrosus (AF). Lactic acid, an abundant end-product of NP glycolysis, has long been viewed as a harmful waste that acidifies disc tissue and decreases cell viability and function. As lactic acid is readily converted into lactate in disc tissue, the objective of this study was to determine whether lactate could be used by AF cells as a carbon source rather than being removed from disc tissue as a waste byproduct.

Methods

Import and conversion of lactate to tricarboxylic acid (TCA) cycle intermediates and amino acids in rabbit AF cells were measured by heavy-isotope (¹³C-lactate) tracing experiments using mass spectrometry. Levels of protein expression of lactate converting enzymes, lactate importer and exporter in NP and AF tissues were quantified by Western blots. Effects of lactate on proteoglycan (³⁵S-sulfate) and collagen (³H-proline) matrix protein synthesis and oxidative phosphorylation (Seahorse XFe96 Extracellular Flux Analyzer) in AF cells were assessed.

Results

Heavy-isotope tracing experiments revealed that AF cells imported and converted lactate into TCA cycle intermediates and amino acids using in vitro cell culture and in vivo models. Addition of exogenous lactate (4 mM) in culture media induced expression of the lactate importer MCT1 and increased oxygen consumption rate by 50%, mitochondrial ATP-linked respiration by 30%, and collagen synthesis by 50% in AF cell cultures grown under physiologic oxygen (2-5% O₂) and glucose concentration (1-5 mM). AF tissue highly expresses MCT1, LDH-H, an enzyme that preferentially converts lactate to pyruvate, and PDH, an enzyme that converts pyruvate to acetyl-coA. In contrast, NP tissue highly expresses MCT4, a lactate exporter, and LDH-M, an enzyme that preferentially converts pyruvate to lactate.

Conclusions

These findings support disc lactate-dependent metabolic symbiosis in which lactate produced by the hypoxic, glycolytic NP cells is utilized by the more oxygenated AF cells via oxidative phosphorylation for energy and matrix production, thus shifting the current research paradigm of viewing disc lactate as a waste product to considering it as an important biofuel. These scientifically impactful results suggest novel therapeutic targets in disc metabolism and degeneration.

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Title: Lactate oxidative phosphorylation by annulus fibrosus cells: evidence for lactate-dependent metabolic symbiosis in intervertebral discs
Authors: Dong Wang
Robert Hartman
Chao Han
Chao-ming Zhou
Brandon Couch
Matias Malkamaki
Vera Roginskaya
Bennett Van Houten
Steven J. Mullett
Stacy G. Wendell
Michael J. Jurczak
James Kang
Joon Lee
Gwendolyn Sowa
Nam Vo
Publication date: 01-12-2021
Publisher: BioMed Central
Published in: Arthritis Research & Therapy / Issue 1/2021
Electronic ISSN: 1478-6362
DOI: https://doi.org/10.1186/s13075-021-02501-2

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