ECSIT is a critical limiting factor for cardiac function
Linan Xu, Fiachra Humphries, Nezira Delagic, Bingwei Wang, Ashling Holland, Kevin S. Edgar, Jose R. Hombrebueno, Donna Beer Stolz, Ewa Oleszycka, Aoife M. Rodgers, Nadezhda Glezeva, Kenneth McDonald, Chris J. Watson, Mark T. Ledwidge, Rebecca J. Ingram, David J. Grieve, Paul N. Moynagh
Linan Xu, Fiachra Humphries, Nezira Delagic, Bingwei Wang, Ashling Holland, Kevin S. Edgar, Jose R. Hombrebueno, Donna Beer Stolz, Ewa Oleszycka, Aoife M. Rodgers, Nadezhda Glezeva, Kenneth McDonald, Chris J. Watson, Mark T. Ledwidge, Rebecca J. Ingram, David J. Grieve, Paul N. Moynagh
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Research Article Cardiology Metabolism

ECSIT is a critical limiting factor for cardiac function

Abstract

Evolutionarily conserved signaling intermediate in Toll pathways (ECSIT) is a protein with roles in early development, activation of the transcription factor NF-κB, and production of mitochondrial reactive oxygen species (mROS) that facilitates clearance of intracellular bacteria like Salmonella. ECSIT is also an important assembly factor for mitochondrial complex I. Unlike the murine form of Ecsit (mEcsit), we demonstrate here that human ECSIT (hECSIT) is highly labile. To explore whether the instability of hECSIT affects functions previously ascribed to its murine counterpart, we created a potentially novel transgenic mouse in which the murine Ecsit gene is replaced by the human ECSIT gene. The humanized mouse has low levels of hECSIT protein, in keeping with its intrinsic instability. Whereas low-level expression of hECSIT was capable of fully compensating for mEcsit in its roles in early development and activation of the NF-κB pathway, macrophages from humanized mice showed impaired clearance of Salmonella that was associated with reduced production of mROS. Notably, severe cardiac hypertrophy was manifested in aging humanized mice, leading to premature death. The cellular and molecular basis of this phenotype was delineated by showing that low levels of human ECSIT protein led to a marked reduction in assembly and activity of mitochondrial complex I with impaired oxidative phosphorylation and reduced production of ATP. Cardiac tissue from humanized hECSIT mice also showed reduced mitochondrial fusion and more fission but impaired clearance of fragmented mitochondria. A cardiomyocyte-intrinsic role for Ecsit in mitochondrial function and cardioprotection is also demonstrated. We also show that cardiac fibrosis and damage in humans correlated with low expression of human ECSIT. In summary, our findings identify a role for ECSIT in cardioprotection, while generating a valuable experimental model to study mitochondrial dysfunction and cardiac pathophysiology.

Authors

Linan Xu, Fiachra Humphries, Nezira Delagic, Bingwei Wang, Ashling Holland, Kevin S. Edgar, Jose R. Hombrebueno, Donna Beer Stolz, Ewa Oleszycka, Aoife M. Rodgers, Nadezhda Glezeva, Kenneth McDonald, Chris J. Watson, Mark T. Ledwidge, Rebecca J. Ingram, David J. Grieve, Paul N. Moynagh

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Figure 4

Proteomic analysis of humanized hECSIT heart.

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Proteomic analysis of humanized hECSIT heart. (A) Volcano plot analysis ...
(A) Volcano plot analysis of differentially expressed proteins in heart tissue from 3- and 10-month-old WT and ECSIT+/+ mice. (B) Heatmap analysis of differentially expressed proteins in heart tissue from 3- and 10-month-old WT versus ECSIT+/+ mice. (C) Heatmap analysis of differentially expressed oxidative phosphorylation-associated mitochondrial proteins in heart tissue from 3- and 10-month-old WT versus ECSIT+/+ mice. (D) STRING network analysis of statistically significant differentially expressed proteins of decreased abundance in heart tissue from 3- and 10-month-old WT and ECSIT+/+ mice. Mitochondrial proteins are highlighted in red. FDRs are computed P values corrected for multiple testing using the method of Benjamini and Hochberg. Data indicate samples from individual mice (n = 3–5 for all groups). (E) Immunoblot analysis of left ventricular cardiac tissue for levels of ECSIT, NDUFS3, Cox IV, Cox V, translocase of outer membrane 20 (Tom20), and GAPDH in WT and ECSIT+/+ mice (n = 3) of 8 to 10 weeks of age. (F and G) Isolated heart mitochondria from WT and ECSIT+/+ mice at (F) 7 months (n = 2) and (G) 10 weeks of age (n = 2) were subjected to BN-PAGE followed by in-gel activity assays using complex I– and complex IV–specific substrates. Complex I activity, as an individual complex or as part of supercomplexes (SC), is shown in violet. Complex IV activity, as an individual complex or as part of supercomplex with complex III, is shown in brown.