Kidney mitochondrial DNA contributes to systemic IL-6 release in sepsis-associated acute kidney injury
Avnee J. Kumar, Katharine Epler, Jing Wang, Alice Shen, Negin Samandari, Mark L. Rolfsen, Laura A. Barnes, Gerald S. Shadel, Alexandra G. Moyzis, Alva G. Sainz, Karlen Ulubabyan, Kefeng Li, Kristen Jepsen, Xinrui Li, Mark M. Fuster, Roger G. Spragg, Roman Sasik, Volker Vallon, Helen Goodluck, Joachim H. Ix, Prabhleen Singh, Mark L. Hepokoski
Avnee J. Kumar, Katharine Epler, Jing Wang, Alice Shen, Negin Samandari, Mark L. Rolfsen, Laura A. Barnes, Gerald S. Shadel, Alexandra G. Moyzis, Alva G. Sainz, Karlen Ulubabyan, Kefeng Li, Kristen Jepsen, Xinrui Li, Mark M. Fuster, Roger G. Spragg, Roman Sasik, Volker Vallon, Helen Goodluck, Joachim H. Ix, Prabhleen Singh, Mark L. Hepokoski
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Research Article Inflammation Nephrology

Kidney mitochondrial DNA contributes to systemic IL-6 release in sepsis-associated acute kidney injury

Abstract

Mitochondrial dysfunction is a major mechanism of acute kidney injury (AKI), and increased circulating interleukin 6 (IL-6) is associated with systemic inflammation and death due to sepsis. We tested whether kidney mitochondrial DNA (mtDNA) contributes to IL-6 release in sepsis-associated AKI via Toll-like receptor 9 (TLR9). In a murine model of sepsis via cecal ligation and puncture (CLP), we used next-generation sequencing of plasma mtDNA to inform the design of optimal target sequences for quantification by droplet digital PCR, and to identify single-nucleotide polymorphisms (SNPs) to infer tissue origin. We found significantly higher concentrations of plasma mtDNA after CLP versus shams and that plasma mtDNA SNPs matched kidney SNPs more than other organs. Kidney mtDNA contributed directly to IL-6 and mtDNA release from dendritic cells in vitro and kidney mitochondria solution led to higher IL-6 concentrations in vivo. IL-6 release was mitigated by a TLR9 inhibitor. Finally, plasma mtDNA was significantly higher in septic patients with AKI compared with those without AKI and correlated significantly with plasma IL-6. We conclude that AKI contributes to increased circulating IL-6 in sepsis via mtDNA release. Targeting kidney mitochondria and mtDNA release are potential translational avenues to decrease mortality from sepsis-associated AKI.

Authors

Avnee J. Kumar, Katharine Epler, Jing Wang, Alice Shen, Negin Samandari, Mark L. Rolfsen, Laura A. Barnes, Gerald S. Shadel, Alexandra G. Moyzis, Alva G. Sainz, Karlen Ulubabyan, Kefeng Li, Kristen Jepsen, Xinrui Li, Mark M. Fuster, Roger G. Spragg, Roman Sasik, Volker Vallon, Helen Goodluck, Joachim H. Ix, Prabhleen Singh, Mark L. Hepokoski

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Figure 3

Circulating cell-free mtDNA is increased in mice after cecal ligation and puncture compared with sham operation.

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Circulating cell-free mtDNA is increased in mice after cecal ligation an...
Plasma concentrations of mtDNA were determined by droplet digital PCR targeting sequences within the cytochrome b (CytB) and NADH dehydrogenase 1 (ND1) genes. These genes were chosen based on their dissimilarity from any region of the nuclear genome based on minimum Hamming distance, and small sequences were targeted to account for fragmentation. Plasma concentrations of CytB (A), ND1a (B), and ND1b (C) were all increased significantly in cecal ligation and puncture (CLP) mice compared with shams at 4 hours. CytB and ND1b remained significantly increased at 24 hours compared with shams, and CytB was also increased significantly at 4 hours versus 24 hours after CLP. (D) The smallest target sequence, CytB, was increased significantly compared with ND1a and ND1b at 4 hours after CLP. (E) Simple linear regression between plasma concentrations of CytB and ND1a and ND1b, respectively, showed a positive and significant correlation for both comparisons. Significant differences between groups were determined by 1-way ANOVA with Tukey’s post hoc analysis. n = 6/group.