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Rianne Nederlof,
Chaoqin Xie,
Otto Eerbeek, Anneke Koeman,
Dan M J Milstein,
Markus W Hollmann,
Egbert G Mik,
Alice Warley,
Richard Southworth,
Fadi G Akar,
Coert J Zuurbier
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ABSTRACT: Rationale: We have shown that partial dissociation of hexokinase II (HKII) from mitochondria in the intact heart using low-dose transactivating transcriptional factor (TAT)-HKII (200 nmol/L) prevents the cardioprotective effects of ischemic preconditioning, whereas high-dose TAT-HKII (10 μmol/L) administration results in rapid myocardial dysfunction, mitochondrial depolarization, and disintegration. In this issue of Circulation Research, Pasdois et al argue that the deleterious effects of TAT-HKII administration on cardiac function are likely because of vasoconstriction and ensuing ischemia. Objective: To investigate whether altered vascular function and ensuing ischemia recapitulate the deleterious effects of TAT-HKII in intact myocardium. Methods and Results: Using a variety of complementary techniques, including mitochondrial membrane potential (Δψ(m)) imaging, high-resolution optical action potential mapping, analysis of lactate production, nicotinamide adenine dinucleotide epifluorescence, lactate dehydrogenase release, and electron microscopy, we provide direct evidence that refutes the notion that acute myocardial dysfunction by high-dose TAT-HKII peptide administration is a consequence of impaired vascular function. Moreover, we demonstrate that low-dose TAT-HKII treatment, which abrogates the protective effects of ischemic preconditioning, is not associated with ischemia or ischemic injury. Conclusions: Our findings challenge the notion that the effects of TAT-HKII are attributable to impaired vascular function and ensuing ischemia, thereby lending further credence to the role of mitochondria-bound HKII as a critical regulator of cardiac function, ischemia-reperfusion injury, and cardioprotection by ischemic preconditioning.
Circulation Research 01/2013; 112(2):e8-e13. · 9.49 Impact Factor
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Kirsten M Smeele,
Otto Eerbeek,
Gert Schaart, Anneke Koeman,
Rick Bezemer,
Jessica K Nelson,
Can Ince,
Rianne Nederlof,
Maxim Boek,
Markku Laakso,
Arnold de Haan,
Maarten R Drost,
Markus W Hollmann,
Coert J Zuurbier
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ABSTRACT: We previously demonstrated that hexokinase (HK) II plays a key role in the pathophysiology of ischemia-reperfusion (I/R) injury of the heart (Smeele et al. Circ Res 108: 1165-1169, 2011; Wu et al. Circ Res 108: 60-69, 2011). However, it is unknown whether HKII also plays a key role in I/R injury and healing thereafter in skeletal muscle, and if so, through which mechanisms. We used male wild-type (WT) and heterozygous HKII knockout mice (HKII(+/-)) and performed in vivo unilateral skeletal muscle I/R, executed by 90 min hindlimb occlusion using orthodontic rubber bands followed by 1 h, 1 day, or 14 days reperfusion. The contralateral (CON) limb was used as internal control. No difference was observed in muscle glycogen turnover between genotypes at 1 h reperfusion. At 1 day reperfusion, the model resulted in 36% initial cell necrosis in WT gastrocnemius medialis (GM) muscle that was doubled (76% cell necrosis) in the HKII(+/-) mice. I/R-induced apoptosis (29%) was similar between genotypes. HKII reduction eliminated I/R-induced mitochondrial Bax translocation and oxidative stress at 1 day reperfusion. At 14 days recovery, the tetanic force deficit of the reperfused GM (relative to control GM) was 35% for WT, which was doubled (70%) in HKII(+/-) mice, mirroring the initial damage observed for these muscles. I/R increased muscle fatigue resistance equally in GM of both genotypes. The number of regenerating fibers in WT muscle (17%) was also approximately doubled in HKII(+/-) I/R muscle (44%), thus again mirroring the increased cell death in HKII(+/-) mice at day 1 and suggesting that HKII does not significantly affect muscle regeneration capacity. Reduced HKII was also associated with doubling of I/R-induced fibrosis. In conclusion, reduced muscle HKII protein content results in impaired muscle functionality during recovery from I/R. The impaired recovery seems to be mainly a result of a greater susceptibility of HKII(+/-) mice to the initial I/R-induced necrosis (not apoptosis), and not a HKII-related deficiency in muscle regeneration.
Journal of Applied Physiology 06/2012; 113(4):608-18. · 3.75 Impact Factor
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ABSTRACT: Recent studies indicate that the innate immune system is not only triggered by exogenous pathogens and pollutants, but also by endogenous danger signals released during ischemia and necrosis. As triggers for the innate immune NLRP3 inflammasome protein complex appear to overlap with those for cardiac ischemia-reperfusion (I/R) and ischemic preconditioning (IPC), we explored the possibility that the NLRP3 inflammasome is involved in IPC and acute I/R injury of the heart.
Baseline cardiac performance and acute I/R injury were investigated in isolated, Langendorff-perfused hearts from wild-type (WT), ASC(-/-) and NLRP3(-/-) mice. Deletion of NLRP3 inflammasome components ASC(-/-) or NLRP3(-/-) did not affect baseline performance. The deletions exacerbated I/R-induced mechanical dysfunction, but were without effect on I/R-induced cell death. When subjected to IPC, WT and ASC(-/-) hearts were protected against I/R injury (improved function and less cell death). However, IPC did not protect NLRP3(-/-) hearts against I/R injury. NLRP3(-/-) hearts had significantly decreased cardiac IL-6 levels with a trend towards lower IL-1β levels at end reperfusion, suggesting abrogation of IPC through diminished IL-6 and/or IL-1β signaling. Subsequent experiments showed that neutralising IL-6 using an antibody against IL-6 abrogated IPC in WT hearts. However, inhibition of the IL-1r receptor with the IL-1 receptor inhibitor Anakinra (100 mg/L) did not abrogate IPC in WT hearts. Analysis of survival kinases after IPC demonstrated decreased STAT3 expression in NLRP3(-/-) hearts when compared to WT hearts.
The data suggest that the innate immune NLRP3 protein, in an NLRP3-inflammasome-independent fashion, is an integral component of IPC in the isolated heart, possibly through an IL-6/STAT3 dependent mechanism.
PLoS ONE 01/2012; 7(7):e40643. · 4.09 Impact Factor
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ABSTRACT: Podocytes of the kidney adhere tightly to the underlying glomerular basement membrane (GBM) in order to maintain a functional filtration barrier. The clinical importance of podocyte binding to the GBM via an integrin-laminin-actin axis has been illustrated in models with altered function of α3β1 integrin, integrin-linked kinase, laminin-521, and α-actinin 4. Here we expanded on the podocyte-GBM binding model by showing that the main podocyte adhesion receptor, integrin α3β1, interacts with the tetraspanin CD151 in situ in humans. Deletion of Cd151 in mouse glomerular epithelial cells led to reduced adhesive strength to laminin by redistributing α3β1 at the cell-matrix interface. Moreover, in vivo podocyte-specific deletion of Cd151 led to glomerular nephropathy. Although global Cd151-null B6 mice were not susceptible to renal disease, as has been shown previously, increasing blood and transcapillary filtration pressure induced nephropathy in these mice. Importantly, blocking the angiotensin-converting enzyme in renal disease-susceptible global Cd151-null FVB mice prolonged their median life span. Together, these results establish CD151 as a crucial modifier of integrin-mediated adhesion of podocytes to the GBM and show that blood pressure is an important factor in the initiation and progression of Cd151 knockout-induced nephropathy.
The Journal of clinical investigation 12/2011; 122(1):348-58. · 15.39 Impact Factor
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Kirsten M A Smeele,
Richard Southworth,
Rongxue Wu,
Chaoqin Xie,
Rianne Nederlof,
Alice Warley,
Jessica K Nelson,
Pepijn van Horssen,
Jeroen P van den Wijngaard,
Sami Heikkinen,
Markku Laakso, Anneke Koeman,
Maria Siebes,
Otto Eerbeek,
Fadi G Akar,
Hossein Ardehali,
Markus W Hollmann,
Coert J Zuurbier
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ABSTRACT: Isoforms I and II of the glycolytic enzyme hexokinase (HKI and HKII) are known to associate with mitochondria. It is unknown whether mitochondria-bound hexokinase is mandatory for ischemic preconditioning and normal functioning of the intact, beating heart.
We hypothesized that reducing mitochondrial hexokinase would abrogate ischemic preconditioning and disrupt myocardial function.
Ex vivo perfused HKII(+/-) hearts exhibited increased cell death after ischemia and reperfusion injury compared with wild-type hearts; however, ischemic preconditioning was unaffected. To investigate acute reductions in mitochondrial HKII levels, wild-type hearts were treated with a TAT control peptide or a TAT-HK peptide that contained the binding motif of HKII to mitochondria, thereby disrupting the mitochondrial HKII association. Mitochondrial hexokinase was determined by HKI and HKII immunogold labeling and electron microscopy analysis. Low-dose (200 nmol/L) TAT-HK treatment significantly decreased mitochondrial HKII levels without affecting baseline cardiac function but dramatically increased ischemia-reperfusion injury and prevented the protective effects of ischemic preconditioning. Treatment for 15 minutes with high-dose (10 μmol/L) TAT-HK resulted in acute mitochondrial depolarization, mitochondrial swelling, profound contractile impairment, and severe cardiac disintegration. The detrimental effects of TAT-HK treatment were mimicked by mitochondrial membrane depolarization after mild mitochondrial uncoupling that did not cause direct mitochondrial permeability transition opening.
Acute low-dose dissociation of HKII from mitochondria in heart prevented ischemic preconditioning, whereas high-dose HKII dissociation caused cessation of cardiac contraction and tissue disruption, likely through an acute mitochondrial membrane depolarization mechanism. The results suggest that the association of HKII with mitochondria is essential for the protective effects of ischemic preconditioning and normal cardiac function through maintenance of mitochondrial potential.
Circulation Research 05/2011; 108(10):1165-9. · 9.49 Impact Factor
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ABSTRACT: In the present study, we examined whether standard chow (SDS versus Purina 5001; both low fat, high carbohydrate) and reductions in hexokinase (HK) II (wild-type versus HKII(+/-) mice) affect (1) growth parameters, (2) HK levels in cardiac and skeletal muscle and (3) low-flow cardiac ischaemia-reperfusion (IR) injury. Total HK activity and HKI and HKII expressions were determined, and low-flow IR injury was examined in isolated hearts subjected to 40 min 5% low-flow ischaemia and 120 min reperfusion. Standard chow, but not HKII reductions, significantly affected body weight, heart weight and cardiac hypertrophy. Both standard chow and reduced HKII diminished total cardiac and skeletal muscle HK activity. For the heart, the Purina chow-induced decrease in total HK activity was through decreases in HKI expression, whereas for skeletal muscle post-translational mechanisms are suggested. Both standard chow and reduced HKII demonstrated a non-significant trend for affecting cardiac IR damage. However, the low-flow ischaemia model was associated with mild sublethal injury only (∼1% cell death). In conclusion, standard chow affects body weight, heart weight and HK activity and HKI expression in the heart, without altering HKII expression. This implicates standard chow as an important factor in genomic, physiological research models and demonstrates that large differences in fat or carbohydrates in the diet are not necessary to affect growth. In a cardiac low-flow IR model, resulting in only mild injury, standard chow or reduced HKII does not significantly affect IR damage.
Laboratory Animals 04/2011; 45(3):160-6. · 1.21 Impact Factor
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Kirsten M Smeele,
Otto Eerbeek, Anneke Koeman,
Rick Bezemer,
Can Ince,
Sami Heikkinen,
Markku Laakso,
Arnold de Haan,
Gert Schaart,
Maarten R Drost,
Markus W Hollmann,
Coert J Zuurbier
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ABSTRACT: Cellular studies have demonstrated a protective role of mitochondrial hexokinase against oxidative insults. It is unknown whether HK protective effects translate to the in vivo condition. In the present study, we hypothesize that HK affects acute ischemia-reperfusion injury in skeletal muscle of the intact animal. Male and female heterozygote knockout HKII (HK(+/-)), heterozygote overexpressed HKII (HK(tg)), and their wild-type (WT) C57Bl/6 littermates mice were examined. In anesthetized animals, the left gastrocnemius medialis (GM) muscle was connected to a force transducer and continuously stimulated (1-Hz twitches) during 60 min ischemia and 90 min reperfusion. Cell survival (%LDH) was defined by the amount of cytosolic lactate dehydrogenase (LDH) activity still present in the reperfused GM relative to the contralateral (non-ischemic) GM. Mitochondrial HK activity was 72.6 +/- 7.5, 15.7 +/- 1.7, and 8.8 +/- 0.9 mU/mg protein in male mice, and 72.7 +/- 3.7, 11.2 +/- 1.4, and 5.9 +/- 1.1 mU/mg in female mice for HK(tg), WT, and HK(+/-), respectively. Tetanic force recovery amounted to 33 +/- 7% for male and 17 +/- 4% for female mice and was similar for HK(tg), WT, and HK(+/-). However, cell survival was decreased (p = 0.014) in male HK(+/-) (82 +/- 4%LDH) as compared with WT (98 +/- 5%LDH) and HK(tg) (97 +/- 4%LDH). No effects of HKII on cell survival was observed in female mice (92 +/- 2% LDH). In conclusion, in this mild model of acute in vivo ischemia-reperfusion injury, a partial knockout of HKII was associated with increased cell death in male mice. The data suggest for the first time that HKII mediates skeletal muscle ischemia-reperfusion injury in the intact male animal.
Pflügers Archiv - European Journal of Physiology 02/2010; 459(5):705-12. · 4.46 Impact Factor
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ABSTRACT: The glycolytic enzyme hexokinase (HK) is suggested to play a role in ischemic preconditioning (IPC). In the present study we determined how ischemic preconditioning affects HK activity and HKI and HKII protein content at five different time points and three different subcellular fractions throughout cardiac ischemia-reperfusion. Isolated Langendorff-perfused rat hearts (10 groups of 7 hearts each) were subjected to 35 min ischemia and 30 min reperfusion (control groups); the IPC groups were pretreated with 3 times 5-min ischemia. IPC was without effect on microsomal HK activity, and only decreased cytosolic HK activity at 35 min ischemia, which was mimicked by decreased cytosolic HKII, but not HKI, protein content. In contrast, mitochondrial HK activity at baseline and during reperfusion was elevated by IPC, without changes during ischemia. No effect of IPC on mitochondrial HK I protein content was observed. However, mitochondrial HK II protein content during reperfusion was augmented by IPC, albeit not following the IPC stimulus. It is concluded that IPC results in decreased cytosolic HK activity during ischemia that could be explained by decreased HKII protein content. IPC increased mitochondrial HK activity before ischemia and during reperfusion that was only mimicked by increased HK II protein content during reperfusion. IPC was without effect on the phosphorylation status of HK before ischemia. We conclude that IPC is associated with 1) a biphasic response of increased mitochondrial HK activity before and after ischemia, 2) decreased cytosolic HK activity during ischemia, and 3) cellular redistribution of HKII but not HKI.
Journal of Applied Physiology 03/2009; 106(6):1909-16. · 3.75 Impact Factor
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ABSTRACT: Recent evidence suggests that hexokinase mitochondria association attenuates cell death, and that plasma glucose and insulin concentrations can influence clinical outcome. In the present study, we examined how different anesthetics per se affect these variables of glucose metabolism, i.e., under similar hemodynamic conditions and in the absence of major surgical stress.
In fed rats, the effects of pentobarbital (PENTO), isoflurane (ISO), sevoflurane (SEVO), ketamine-medetomidine-atropine (KMA), and sufentanil-propofol-morphine (SPM) on the cardiac cellular localization of hexokinase (HK) and levels of plasma glucose and insulin were determined and compared with values obtained in nonanesthetized animals (control). The role of mitochondrial and sarcolemmal K(ATP)-channels and alpha2-adrenergic receptor in ISO-induced hyperglycemia was also evaluated.
Mean arterial blood pressure was similar among the different anesthetic strategies. PENTO (5.3 +/- 0.2 mM) and SPM (5.1 +/- 0.2 mM) had no significant effect on plasma glucose when compared with control (5.6 +/- 0.1 mM). All other anesthetics induced hyperglycemia: 7.4 +/- 0.2 mM (SEVO), 9.9 +/- 0.3 mM (ISO), and 14.8 +/- 1.0 mM (KMA). Insulin concentrations were increased with PENTO (2.13 +/- 0.13 ng/mL) when compared with control (0.59 +/- 0.22 ng/mL), but were unaffected by the other anesthetics. Inhibition of the mitochondrial K(ATP) channel (5-hydroxydecanoate acid) or the alpha(2)-adrenergic receptor (yohimbine) did not prevent ISO-induced hyperglycemia. Only the nonspecific K(ATP) channel inhibitor glibenclamide was able to prevent hyperglycemia by ISO. Cytoslic HK relative to total HK increased in the following sequence: control (35.5% +/- 2.1%), SEVO (35.5% +/- 2.7%), ISO (36.6% +/- 1.7%), PENTO (41.2% +/- 2.0%; P = 0.082 versus control), SPM (43.0% +/- 1.8%; P = 0.039 versus control), and KMA (46.6 +/- 2.3%; P = 0.002 versus control).
Volatile anesthetics and KMA induce hyperglycemia, which can be explained, at least partly, by impaired glucose-induced insulin release. The data indicate that the inhibition of insulin release by ISO is mediated by sarcolemmal K(ATP) channel activation. The use of PENTO and SPM is not associated with hyperglycemia. SPM and KMA reduce the antiapoptotic association of HK with mitochondria.
Anesthesia and analgesia 02/2008; 106(1):135-42, table of contents. · 3.08 Impact Factor
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ABSTRACT: Hyperglycemia is becoming recognized as an important risk factor for microvascular dysfunction. We hypothesized that short-term hyperglycemia, either on the scale of hours or weeks, alters the barrier function and the volume of the endothelial glycocalyx and decreases functional capillary density and deformability of the red blood cells (RBCs). All experiments were performed in anesthetized, mechanically ventilated, C57BL/6 mice that were either normoglycemic, acutely hyperglycemic (25 mM) for 60 min due to infusion of glucose, or hyperglycemic (25 mM) for 2-4 wk (db/db mice). The glycocalyx was probed using 40-kDa Texas red dextran, which is known to permeate the glycocalyx, and 70-kDa FITC dextran, which has impaired access to the glycocalyx in healthy animals. Clearance of the dye from the blood was measured. An orthogonal polarization spectral imaging technique was used to visualize the number of capillaries with flowing RBCs of the dorsal flexor muscle. The data indicate that short-term hyperglycemia causes a rapid decrease of the ability of the glycocalyx to exclude 70-kDa dextran. No change in the vascular permeation of 40-kDa dextran was observed. Glycocalyx volume was not affected by short-term hyperglycemia. In addition, 1 h of hyperglycemia resulted in a 38% decrease of the lineal density of capillaries with flowing RBCs. This decreased lineal density was not observed in the 2- to 4-wk hyperglycemia model. Short-term hyperglycemia was without any effect on the deformablity of the RBCs. The data indicate that the described increased vascular permeability with hyperglycemia can be ascribed to an increased permeability of the glycocalyx, identifying the glycocalyx as a potential early target of hyperglycemia.
Journal of Applied Physiology 11/2005; 99(4):1471-6. · 3.75 Impact Factor
