Regulation of Mitochondrial Dynamics by Dynamin-Related Protein-1 in Acute Cardiorenal Syndrome

Discussion

Complication of heart and kidney dysfunction in critically ill patients has a substantial effect on patient outcomes. These two disorders worsen each other synergistically. Therefore, identifying the pathway of organ interaction between the heart and kidney is expected to be crucial for developing targeted therapies to improve the outcomes. This study demonstrated, for the first time ever reported to our knowledge, that the depression of cardiac function caused by AKI was associated with morphologic effect on the heart, as evidenced by mitochondrial fragmentation and apoptosis, and that Drp1 activation plays a crucial role in AKI-induced cardiac injury (acute renocardiac syndrome). It should be addressed that a Drp1 inhibitor mdivi-1 suppressed cardiac injury after renal IR, even when administered 6 h after renal ischemia insult.

The kidney and heart require large amounts of energy production. Therefore, they are rich in mitochondria. Consequently, it can be assumed that mitochondrial damage contributes to the pathogeneses of acute kidney and heart dysfunction. Recently, Brooks and colleagues reported a remarkable morphologic change of mitochondria in acute kidney injury models, including IR and cisplatin injection.¹⁵ Mitochondrial fragmentation was observed earlier than cytochrome c release and cellular apoptosis. Dominant-negative and small interfering RNA knockdown experiments demonstrated the role of Drp1 in mitochondrial fragmentation.¹⁵ Sharp and colleagues showed that Drp1 activation during cardiac IR caused left ventricle dysfunction, which was reversed by Drp1 inhibition.¹⁷ This study demonstrated that renal IR caused cardiac mitochondrial damage via Drp1 activation. This result might support the view that mitochondrial fission by Drp1 activation is a common pathway by which IR injury in one organ causes injury to another remote organ.

Mitochondria fragmentation describes abnormally small mitochondria and is reportedly observed in apoptotic cells.^18,19 A crucial role for mitochondrial fragmentation in apoptosis has been reported.²⁰ A molecular pathway in which increased mitochondrial fission induces cellular apoptosis by Drp1 activation has been suggested. Frank and colleagues reported that inhibition of Drp1 by overexpressing dominant-negative mutant in cultured cells prevented the release of cytochrome c and suppressed apoptosis.²¹ Germain and colleagues reported that Drp1-dependent cristae remodeling caused cytochrome c release from mitochondria.²² Recently, Ban-Ishihara reported that Drp1-dependent mitochondrial fission regulates cytochrome c release via mitochondrial DNA distribution and cristae reformation.²³

Presumably, mitochondrial fragmentation is determined as a balance between fission and fusion of mitochondria. Although accumulation of fission GTPase Drp1 on mitochondria during apoptosis has been reported by several studies,^21,24–26 insufficient mitochondrial fusion might also contribute to cellular apoptosis. Three large GTPases in the dynamin family mediate mitochondrial fusion: Mfn1, Mfn2, and OPA1. These fusion GTPases are reportedly related to apoptosis.^27,28 However, no change of their expressions was found in mitochondrial fractions or whole tissue lysates of the heart after renal IR in this study. Therefore, mitochondrial fragmentation appeared to be caused mainly by fission machinery in AKI-induced cardiac injury. These results were obtained using Western blot analysis with the mitochondria fraction extracted from heart tissue. Because electron microscopy of the heart tissue showed more fragmented mitochondria in the renal IR group than in the sham group, evaluation of mitochondrial dynamics regulation molecules of Drp1, Mfn1, Mfn2, and OPA1 was influenced by the different number of fragmented mitochondria between these two groups. However, we observed a difference of protein amounts between the renal IR and sham groups not in Mfn1, Mfn2, OPA1, but in Drp1 only. Moreover, we observed reduced mitochondrial fragmentation by Drp1 inhibition in the experiment of mdivi-1 treatment. Therefore, mitochondrial fragmentation observed in the heart of the renal IR group might be caused at least partly by a Drp1-dependent pathway.

Drp1 is an intensively investigated mitochondrial fission–regulating molecule. Approximately 97% of Drp1 is located in the cytoplasm under normative conditions. However, Drp1 will translocate to the outer membrane of mitochondria by activation and initiate the mitochondrial fission process. Several post-translational modifications, such as serine phosphorylation and ubiquitin E3 ligase, regulated Drp1 activity.^29,30 An inhibitor of mitochondrial division has been identified using yeast screening of chemical libraries.³¹ This compound (mdivi-1) inhibits Drp1 assembly and GTPase activity. It also inhibits subsequent mitochondrial fission. Therefore, mdivi-1 is used widely for exploration of the role of mitochondrial fission in apoptosis. Protection by mdivi-1 administration against organ dysfunction, including that of the heart and kidney, has already been reported in mouse IR injury models.^15–17 In accordance with these reports, we showed protection by mdivi-1 of cardiac injury caused by AKI, addressing the role of Drp1 in the pathophysiology of remote organ injury by AKI. Although pharmacokinetic properties, including the half-life of mdivi-1 in vivo, are not known, several in vivo studies have demonstrated protection by mdivi-1 in different organ IR injury models at 12–48 h after mdivi-1 injection.^15,16,32,33 This study showed reduced Drp1 assembly to the mitochondrial fraction at 24 h and suppression of apoptosis in the heart at 72 h; however, it remains unclear whether mdivi-1 worked only at the initiation phase of renal ischemia-induced cardiac injury or prolonged effects of mdivi-1 suppress cardiac cell apoptosis.

Results of this study do not clarify why Drp1 in the cardiomyocytes was activated by renal IR injury. Several possible pathways can be considered. First, unknown humoral mediator accumulated in blood circulation attributable to decreased renal clearance might induce Drp1 activation. We recently demonstrated increased blood high-mobility group protein B1–induced lung injury via toll-like receptor 4 in another mouse AKI model of bilateral nephrectomy.³⁴ Second, IR injury to one organ might cause systemic reaction, possibly mediated by inflammatory cytokines or cells. Andrés-Hernando and colleagues reported that proinflammatory cytokines IL-6, chemokine (C-X-C motif) ligand 1, IL-1β, and TNF-α were increased not only in the kidney, but in the spleen and liver in renal IR injury.³⁵ Awad and colleagues observed a marked increase of neutrophil margination in the lungs in a mouse renal IR model.³⁶ Patschan and colleagues demonstrated that endothelial progenitor cell homing to the spleen was induced by renal IR.³⁷ We observed increased TNF-α expression in the heart after renal IR injury in accordance with a previous report.⁹ However, a Drp1 inhibitor, mdivi-1, did not reduce TNF-α expression in the heart; however, it reduced cardiomyocyte apoptosis. These results suggest that TNF-α does not play a crucial role in mitochondrial fragmentation and apoptosis in this model of cardiac injury after renal IR. Drp1 activation by TNF-α can be inhibited by mdivi-1 because this additional experiment cannot exclude the role of TNF-α–induced Drp1 activation. Further investigation must be conducted to ascertain the responsible pathways in cardiac injury caused by renal IR. Additionally, we did not clarify the mechanism by which cardiomyocyte apoptosis caused decreased cardiac function evaluated by functional shortening of the left ventricle. More detailed evaluation of cardiac function using ultrasound and other methods should be done in future studies.

Although mdivi-1 treatment attenuated cardiac injury after renal IR in this study, no significant renal protection by mdivi-1 was observed. A previous report described significant protection of mdivi-1 treatment in vivo on the same AKI model of mouse renal IR injury.¹⁵ However, a marked difference exists between these studies; the animal model in the previous study appears to be more severe because BUN and blood creatinine in the vehicle-treated mice were much higher in the previous study than those in this study (BUN 250 versus 150 mg/dl, creatinine 2.5 versus 1.2 mg/dl). Therefore, it is possible that severity of renal ischemic insult has some effect on the benefit from mdivi-1 treatment. In addition, the optimal dose and timing of mdivi-1 treatment for renal protection might be different from those for cardiac protection. These issues should be investigated further.

In conclusion, this study demonstrated that Drp1-mediated mitochondrial fragmentation and subsequent organ disorder was caused in the heart during renal IR injury. Although clinical situations in which AKI results in acute cardiac dysfunction are observed frequently and are defined recently as acute renocardiac syndrome,⁴ the pathophysiology of this syndrome has not been well demonstrated. Therefore, results obtained from this study strongly suggest that mitochondria fission and apoptosis in the heart as a distant organ effect by AKI should be regarded seriously. They can be good therapeutic targets to improve critically ill patients.