Role Of Mitochondrial Therapy For Ischemic-Reperfusion Injury And Acute Kidney Injury

edmund.chen@wecistanche.com

Abstract

Acute kidney injury (AKI) is a common clinical disorder associated with decline in renal function because of ischemic  and nephrotoxic insults. The pathophysiology of AKI involves multiple cellular mechanisms, such as kidney parenchymal cell (epithelial and endothelial) dysfunction and immune-cell infiltration. Mitochondrial injury which causes  ATP depletion and triggers apoptosis and necrosis is at the  heart of ischemia reperfusion injury (IRI). Pharmacological  (SS-31 or MitoQ), cellular (dendritic cells or mesenchymal  stem cells), or genetic strategies that either directly or indirectly preserve mitochondrial integrity and function have  been shown to mitigate IRI-linked AKI in preclinical models.  Interestingly, isolated mitochondria have been recently  shown to be taken up by various mammalian cells resulting  in incorporation of transplanted mitochondria into the endogenous mitochondrial network of recipient cells and contributing to protection from ischemic injury in various preclinical models of ischemia including the heart, liver, and  kidneys. The mini review summarizes the current available  therapeutic strategies that improve kidney function by targeting mitochondria health.

Keywords: Acute kidney injury; Mitochondria; Ischemia reperfusion injury; kidney injury; renal function

Introduction

Kidney ischemia-reperfusion injury (IRI) is a major  cause of acute kidney injury (AKI), which in addition to  kidney transplantation occurs in various other clinical  settings such as cardiac surgery, sepsis, and shock. The  pathophysiology of IRI is complex and involves various  aspects including hypoxic injury that results in production of reactive oxygen species, triggering a cycle of cell  Contribution from the AKI and CRRT 2021 Symposium at the 26th  International Conference on Advances in Critical Care Nephrology, A  Virtual/Hybrid Event from San Diego, CA, USA, February 28–March 5,  2021. This symposium was supported in part by the NIDDK funded  University of Alabama at Birmingham-University of California San Diego O’Brien Center for Acute Kidney Injury Research (P30DK079337). death and inflammation between epithelial and immune  cells. In addition to their functional roles as metabolic  energy producers, mitochondria can also regulate cell  death. IRI involves an intricate cascade of events at the  mitochondrial level that includes rapid loss of energy, decrease in mitochondrial membrane potential, and loss in  ionic hemostasis and culminates in ROS production and  cell death. These observations suggest that mitochondria  are critical organelles that undergo major pathophysiological changes during IRI. Importantly, mitochondria  have a critical role not only in initiation and progression  of ischemic injury but also are involved in recovery and  processes that contribute to progression to chronic kidney disease. Multiple mitochondria-targeted pharmacological (SS-31 [1] or MitoQ), cellular (mesenchymal stromal cells [2] or bone marrow-derived dendritic cells [3]),  and recently mitochondria transplant [4] therapeutic  strategies have been tested to improve mitochondrial  health to ultimately reduce dysfunction in preclinical  models of kidney IRI. Although these pharmacological  and cellular therapeutics have shown some benefits in  preserving kidney health, their progression to use in a  clinical setting is limited due to bioavailability and offtarget adverse effects. Additionally, these studies lack a  larger animal model (pigs) to further demonstrate their  potential use, especially if direct delivery to kidneys is  needed. Therapeutic use of mitochondrial transplantation to prevent injury has been demonstrated in various  preclinical models of ischemic injury in multiple organs including the heart, liver, kidney, and lung. The dosing  and treatment strategies of these studies are summarized  in the current review.

CISTANCHE WILL IMPROVE KIDNEY/RENAL FAILURE

Involvement of Mitochondria in Kidney IRI  Under normal healthy states, the electron transport  along the electron transport chain (ETC) is coupled to  oxidative phosphorylation for producing ATP. Water is  the ultimate byproduct of the oxygen consumed in the  ETC that generates electrons as it moves through complex I to complex IV. The small amounts of ROS produced in ETC are needed to maintain the redox state of  cells and is crucial for the function of various enzymes. In ischemia, there is a decrease in activity at various complexes that results in electron leak and reduces oxygenforming superoxide radicals when oxygen is available  upon reperfusion, ultimately reducing the amount of  ATP available. Within the kidneys, the proximal tubules  (PTs) have the highest density of mitochondria, and PT epithelial cells are heavily dependent on oxidative phosphorylation for carrying out normal fluid and solute  transport. During ischemia, in addition to diminished  mitochondrial function, ultrastructural analysis reveals  fragmented mitochondria within 15 min of reperfusion,  ultimately resulting in mitochondria swelling and disruption of tightly packed cristae [5, 6]. These pathophysiological changes associated with IRI indicate that mitochondrial morphology and function are highly coordinated and can rapidly respond to metabolic and cellular  stress. The pathogenesis of kidney IRI involves multiple  complex interactions between kidney parenchymal cells  and infiltrating immune cells [7]. In response to either is chemic injury or toxins, the degradation of the cellular  functions can be triggered by the release of ROS from  damaged mitochondria. Structural damage to mitochondria occurs within few minutes of reperfusion that leads  to release of cytochrome c and the further release of mitochondrial DNA that can further trigger apoptosis [8].  In mouse models of kidney IRI, PT mitochondrial membrane potential decreases quickly, resulting in shorter  fragmented mitochondria than in sham-operated mice.  To observe these structural changes in PT mitochondria,  we generated PT-specific mitochondria reporter mice to  use as a tool to assess mitochondria morphology in various mouse models of AKI. Interestingly, these mice can  also be used to evaluate the released mitochondria after  injury in various other compartments including the  spleen, liver, and urine. Thus, this further allows for evaluation of how targeted release of mitochondria from the  damaged organ may influence distal organ injury due to  its ability to act as mitochondria-damage-associated molecular pattern. PepcKCre mice (a gift from Dr. Volker  Haase, Vanderbilt University) were bred to the Phamfl/fl (purchased from Jackson Laboratory) to produce the  transgenic PepcKCrePhamfl/fl mice that have PT mitochondria labeled with a fluorescent green tag. These mice  were used for either sham or bilateral ischemia of 26 min  with 24 h of reperfusion. The blood was collected under  anesthesia from the retro-orbital sinus, and plasma creatinine (mg/dL) was determined by using an enzymatic  method from the manufacturer’s protocol (Diazyme Laboratories, Poway, CA, USA), and blood urea nitrogen  (BUN) and creatinine measurements were performed using the QuantiChrom Urea Assay Kit (DIUR-100). Compared to sham mice, IRI results in a significant raise in  plasma creatinine (Fig. 1a) and BUN (Fig. 1b). For histology, kidneys were fixed overnight in 10% formalin and  embedded in paraffin. Kidneys were prepared for H&E.  For quantification of tubular injury score (acute tubular 

necrosis), sections were assessed by counting the percentage of tubules that displayed cell necrosis, loss of brush  border, cast formation, and tubule dilation as follows: 0 =  normal; 1 = <10%; 2 = 10–25%; 3 = 26–50%; 4 = 51–75%;  and 5 =>75%. Five to 10 fields from each outer medulla  were evaluated and scored in a blinded manner. Kidneys  of IRI mice had increased acute tubular necrosis compared to sham mice (Fig.  1c) and representative H&E  from sham and IRI kidney (Fig. 1d). Additionally, changes in mitochondria morphology in PepcKCrePhamfl/fl mice shown in sham mice mitochondria are uniformly  aligned in the PTs, whereas the mitochondria morphology is disrupted after IRI (Fig. 1e). The presence of the mitochondria signal (green) was further confirmed to be  localized in the PT segment of the kidney in the PepcKCrePhamfl/fl mice by labeling with CD13 against the PT  brush border and CD31 (PECAM) for the endothelium  (Fig. 1f).

Mitochondrial Therapy and IRI  There are few studies to date in various preclinical  models of IRI that demonstrate mitochondrial transplantation can be used as a therapeutic modality to alleviate or treat IRI-related dysfunction. A comprehensive review  of the models, sources, doses, and route of delivery of isolated mitochondria in various models is listed below. Heart  In a series of studies, the McCully's group has demonstrated that heart IRI can be significantly improved by transplant of isolated mitochondria. Overall, in the heart  IRI models (swine and rabbits), their group demonstrates  that injected mitochondria are specifically taken up by  cardiomyocytes and contribute to enhanced oxygen consumption, high-energy phosphate synthesis, overall reduced cytokine production, preserved myocardial energetics and cell viability, and overall enhanced post-infarct  cardiac function. The McCully group in 2017 reported  the first clinical application of therapeutic mitochondria  in pediatric patients with regions of myocardial akinesis  or hypokinesis. In these 5 patients, viable mitochondria  were isolated from an autologous 6 × 6-mm piece of  healthy rectus abdominis and injected at a dose of 1 × 108 ± 1 × 105  with 1 × 107  ± 1 × 104 /0.1 mL per site [9]. Four  of five patients with single mitochondria transplant, although at multiple sites, improved ventricular function,  and these patients were successfully taken off from extracorporeal mechanical support.

Source  Mitochondria were isolated from muscle (pectoralis major) by a standard protocol developed by the McCully group that takes 30 min without any differential centrifugation steps for all in vivo studies [10]. 

Model  Rabbit heart IRI (30 min of ischemia with 2 h to 28  days of reperfusion). Isolated mitochondria (9.7 × 106  ±  1.7 × 106 /mL, 1.2 × 106 /0.1 mL at 8 sites) were injected at  the time of reperfusion [11]. Swine heart IRI (25 min of  ischemia with 28 days of reperfusion). Isolated mitochondria (9.9 × 107  ± 1.4 × 107 /mL, 1.3 × 107 /0.1 mL at 8 sites)  were injected at time of reperfusion [12]. All mitochondria directly injected into the heart at the regional ischemia sites.

Kidney  In kidney IRI, 2 recently published studies have demonstrated in small and large animal models the therapeutic use of isolated healthy mitochondria. Our collaborative work with McCully’s group used a large swine model  [4] and rats [13]. In the larger animal model, Doulamis et  al. [4], concluded that injected mitochondria significantly protected kidneys from ischemic injury with improved  kidney function, less histological damage, lower coagulative necrosis of the PTs, and lower kidney levels of IL6 [4].  In rats, mitochondria treated animals had significantly  lower creatine and BUN starting at 12 h of reperfusion  and remained significant until 72 h. Interestingly, both  vehicle and mitochondria treated animals had similar levels of creatinine and BUN at the 1 week time point. Overall, the mitochondria treated rats had significantly higher kidney expression of Ki67, PCNA, aquaporin 1 (AQP1,  PT marker) and lower levels of Kim1, cystatine C, and  TUNEL [13]. Both set of studies concluded by stating that  direct injection of isolated healthy mitochondria significantly protects the kidneys from IRI and potentially helps  with repair by increasing the proliferative capacity of the  injury epithelium.

CISTANCHE WILL IMPROVE KIDNEY/RENAL PAIN

Source  Swine, mitochondria were isolated from sternocleidomastoid muscle [10]. Rats, mitochondria were isolated  from pectoralis major muscle [10].  Model  Swine kidney IRI (60 min of ischemia with 24 h of reperfusion). Isolated autologous mitochondria (1 × 109 /6  mL, single ×1 or multiple ×3) were injected intra-arterial at time of reperfusion [4]. Rat kidney IRI (Unilateral,  right-kidney nephrectomy and 45 min of left-kidney is chemia with up to 1 week of reperfusion). Isolated mitochondria (7.5 × 106 /1 mL, 0.4 mL injected) were injected  into the renal artery at the time of reperfusion [13].  Liver  In the study by Lin et al. [14], it was demonstrated that  rats treated with freshly isolated mitochondria 45 min after liver IRI are significantly protected compared to vehicle-treated mice. Rats treated with mitochondria had less  liver injury with lower ALT levels, less congestion hemorrhage, necrosis of the hepatocytes, and less TUNEL-positive cells.  Source  Mitochondria isolated from the rat liver by a standard  differential centrifugation method.  Model  Rat liver IRI (45 min of ischemia with 4 h of reperfusion). Isolated mitochondria (7.7 × 106  ± 1.5 × 106 /mL)  were injected through an intrasplenic injection at the time of reperfusion.  Lung  In this study by Zhu et al. [15], the author used a rat  hypoxic pulmonary hypertension model to assess the  therapeutic use of mitochondria transplantation. Rats  treated with mitochondria had reduced chronic hypoxia induced pulmonary vascular remodeling that resulted in prevention of pulmonary hypertension. Additionally, the current study also demonstrated that mitochondria transplantation can also be used to treat rats that had established chronic hypoxia.  Source  Smooth-muscle cells from explanted pulmonary and  femoral arteries. The methods used for isolating mitochondria were not listed.  Model  Rats were housed in a hypoxic chamber (10% O2) for  8 h a day for 4 weeks. The rats were intravenously treated  with 2.25 × 108  (∼2 µg protein) mitochondria every other  day for 2 weeks, either 2 weeks or 4 weeks after start of  study

Conclusion  The potential use of mitochondria as a treatment modality has been demonstrated to improve disease outcomes  in various preclinical models. Unlike mitochondria-centric pharmacological and cellular treatment strategies, current studies using exogenous mitochondria have reported  no adverse side effects. Unanimously, one of the limitations acknowledged by all studies was that exogenous mitochondria must be freshly isolated, kept cold, and utilized  within a few hours. The use of isolated viable healthy mitochondria as a therapeutic modality to supplement and  functionally improve and potentially replace damaged mitochondria is a viable option. Labeled and injected mitochondria either via a local or systemic injection are taken  up by various cell types. Viability of mitochondria is critical as nonviable or damaged mitochondria and mitochondrial products (DNA, RNA, protein, ATP, and complexes)  do not provide any protection [16]. The injected mitochondria improve the energetics of the recipient cells [11],  induces mitochondrial biogenesis (activates Pgc1a, Bajwa  unpublished observations), increases proliferative capacity  [13], and decreases inflammatory cytokines overall. Interestingly, some critical questions remain. How do exogenous mitochondria get into the cells? In an in vitro setting,  the use to inhibitors of macropinocytosis or a macropinocytosis-like mechanism [17] or microtubules/tunneling  nanotubes or gap junctions [18] partially blocks mitochondria update. How long do the injected mitochondria last?  Although difficult, these studies can be done by taking advantage of the fact that mitochondria come with their own  DNA, so using xenograft mitochondrial transplants to  evaluate the location of systemically injected mitochondria  could be utilized for addressing both the where and how  long does injected mitochondria last. These studies also  have additional limitations as this technique will only allow  detection of injected mitochondrial DNA and cannot be  used to test if injected mitochondrial is functional. Depending on the disease model, how often does the mitochondria need to be injected? In acute settings, a single  dose of mitochondria seems to be adequate, but no current  studies have evaluated the use of mitochondria in chronic  settings. These low doses of mitochondria inhibited acute  hypoxia-triggered pulmonary vasoconstriction and attenuated hypoxia-induced vascular remodeling although the  signal associated with systemic mitochondria injection was  found in the kidney, liver, and spleen. Does the route of  injection matter? In most of the preclinical ischemic rodent models except for the heart, the isolated exogenous  mitochondria are injected systemically via an intravenou route. However, use of larger animal models could be tested to use localized delivery to the target organ as recently  demonstrated by Doulamis et al. [4] using an intra-arterial  injection in a pig kidney IRI model of AKI. Localized delivery of mitochondria could potential also be beneficial as  these interventions may require a lower dose of isolated  mitochondria. Although recently studies have added to  our current knowledge of how the mitochondria transplantation could be utilized as a potential therapeutic strategy, many other questions remain. What is the optimal  dose of mitochondria that is needed for clinical use? Does  the source of mitochondria matter? Does it induce a proinflammatory response, autologous versus syngeneic versus allogenic versus xenogeneic? All published studies use  freshly isolated mitochondria within an hour of isolation.  Can mitochondria be preserved after isolation? Having  mitochondria that can be available for transplantation as  an off-the-shelf treatment strategy could revolutionize the  way we use it as a therapeutic modality to treat diseases.  Finally, transplantation of viable healthy mitochondria  provides a novel therapeutic treatment option to prevent  and treat and to improve disease progression in various  preclinical models. These treatment options using organelles to improve disease outcomes could have a significant  clinical impact.

CISTANCHE WILL IMPROVE KIDNEY/RENAL FUNCTION