Characterization of the structural, oxidative, and immunological features of testis tissue from Zucker diabetic fatty rats.

The purpose of this study was to characterize the testicular profile of Zucker diabetic fatty (ZDF) rats presenting with type 2 diabetes mellitus (DM2) in the absence or presence of obesity. To achieve this, testes were collected from 270-day-old male Wistar (n = 15), ZDF nonobese (n = 15), and ZDF obese rats (n = 16). Changes to the testicular structure were quantified morphometrically, while immunocytochemistry was employed to assess caspase-3 activity. Reactive oxygen species (ROS) production, fluctuations of major antioxidant molecules, and the extent of damage to the proteins and lipids were assessed in tissue lysates. Levels of selected interleukins (ILs) were determined by enzyme-linked immunosorbent assay. The results reveal significant alterations to the testicular structure accompanied by caspase-3 overexpression, particularly in ZDF obese rats. The most notable disruption of the oxidative balance, characterized by ROS overproduction, antioxidant deficiency, protein, and lipid deterioration was recorded in ZDF rats suffering from both DM2 and obesity. Accordingly, the highest concentrations of pro-inflammatory IL-1, IL-6, and IL-18 accompanied by reduced levels of the anti-inflammatory IL-10 were found in testicular tissue collected from ZDF obese rats. This study highlights the vulnerability of male gonads to pathophysiological changes caused by hyperglycemia, which are further exacerbated by excessive adipose tissue.

Na,K-ATPase Kinetics and Oxidative Stress in Kidneys of Zucker Diabetic Fatty (fa/fa) Rats Depending on the Diabetes Severity-Comparison with Lean (fa/+) and Wistar Rats.

For a better insight into relations between type 2 diabetes mellitus (T2DM) and Na,K-ATPase properties in kidneys, we aimed to characterize two subgroups of ZDF obese (fa/fa) rats, with more and less developed T2DM, and compare them with two controls: lean (fa/+) and Wistar. Na,K-ATPase enzyme kinetics were estimated by measuring the ATP hydrolysis in the range of NaCl and ATP levels. As Na,K-ATPase is sensitive to oxidative stress, we evaluated selected oxidative stress parameters in kidney homogenates. Our results suggest that thiol-disulfide redox balance in the renal medulla and Na,K-ATPase properties in the renal cortex differ between both controls, while observed measurements in lean (fa/+) rats showed deviation towards the values observed in ZDF (fa/fa) rats. In comparison with both controls, Na,K-ATPase enzyme activity was higher in the renal cortex of ZDF rats independent of diabetes severity. This might be a consequence of increased glucose load in tubular fluid. The increase in lipid peroxidation observed in the renal cortex of ZDF rats was not associated with Na,K-ATPase activity impairment. Regarding the differences between subgroups of ZDF animals, well-developed T2DM (glycemia higher than 10 mmol/L) was associated with a higher ability of Na,K-ATPase to utilize the ATP energy substrate.

ZDF (fa/fa) rats show increasing heterogeneity in main parameters during ageing, as confirmed by biometrics, oxidative stress markers and MMP activity.

NEW FINDINGS: What is the central question of this study? The aim was to characterize Zucker diabetic fatty [ZDF (fa/fa)] rats and two control strains [Wistar and lean ZDF (fa/+) rats] during ageing. What is the main finding and its importance? Zucker diabetic fatty (fa/fa) rats with lower glycaemia have higher body and left ventricular weights and lower plasma gelatinase activity compared with hyperglycaemic rats. Given that type 2 diabetes is a heterogeneous metabolic disorder, the inhomogeneity of ZDF (fa/fa) rats might be beneficial in the study of its different aspects. Our experiments might promote a discussion regarding suitable normoglycaemic control animals for aged ZDF (fa/fa) rats, especially in experiments focused on myocardial tissue. ABSTRACT: Zucker diabetic fatty [ZDF (fa/fa)] rats, which are an animal model for the study of type 2 diabetes, are considered as a uniform group in most experimental studies; however, there are indications of their increasing inhomogeneity over time. The main objective of our study was to monitor biometric and biochemical parameters of ZDF (fa/fa) rats during their development of type 2 diabetes and compare them with two control strains [Wistar and lean ZDF (fa/+) rats]. According to fasting glycaemia, ZDF (fa/fa) rats were split arbitrarily into two phenotypes: obese, ZDF (fa/fa) FAT; and diabetic, ZDF (fa/fa) DIA. Glycaemia increased progressively only in the ZDF (fa/fa) DIA animals, which also exhibited higher cholesterol levels compared with ZDF (fa/fa) FAT animals. In addition, ZDF (fa/fa) FAT rats revealed more pronounced left ventricular hypertrophy and higher body weight, differentiating them from ZDF (fa/fa) DIA rats. We also investigated the activity of matrix metalloproteinases (MMPs), which are multifunctional enzymes involved in tissue remodelling. Rats in the ZDF (fa/fa) FAT group revealed lower plasma MMP2 and MMP9 activity compared with the ZDF (fa/fa) DIA group. However, increased myocardial MMP2 activity indicated left ventricular remodelling in both ZDF phenotypes. Given that type 2 diabetes in humans is a heterogeneous metabolic disorder, the heterogeneity of ZDF (fa/fa) rats might be beneficial in the study of different aspects of this pathology. Moreover, Wistar rats could serve as a more appropriate control for aged ZDF (fa/fa) rats than the commonly used ZDF fa/+ rats, which showed an increase in left ventricular weight, carbonyl stress markers in the left myocardium and MMP2 activity in both ventricles, indicating heart remodelling processes compared with the Wistar control group.

Toward the Decipherment of Molecular Interactions in the Diabetic Brain.

Diabetes mellitus (DM) has been associated with cognitive complications in the brain resulting from acute and chronic metabolic disturbances happening peripherally and centrally. Numerous studies have reported on the morphological, electrophysiological, biochemical, and cognitive changes in the brains of diabetic individuals. The detailed pathophysiological mechanisms implicated in the development of the diabetic cognitive phenotype remain unclear due to intricate molecular changes evolving over time and space. This review provides an insight into recent advances in understanding molecular events in the diabetic brain, focusing on cerebral glucose and insulin uptake, insulin action in the brain, and the role of the brain in the regulation of glucose homeostasis. Fully competent mitochondria are essential for energy metabolism and proper brain function; hence, the potential contribution of mitochondria to the DM-induced impairment of the brain is also discussed.

Global brain ischemia in rats is associated with mitochondrial release and downregulation of Mfn2 in the cerebral cortex, but not the hippocampus.

Mitochondria are crucial for neuronal cell survival and death through their functions in ATP production and the intrinsic pathway of apoptosis. Mitochondrial dysfunction is considered to play a central role in several serious human diseases, including neurodegenerative diseases, such as Parkinson's and Alzheimer's disease and ischemic neurodegeneration. The aim of the present study was to investigate the impact of transient global brain ischemia on the expression of selected proteins involved in mitochondrial dynamics and mitochondria­associated membranes. The main foci of interest were the proteins mitofusin 2 (Mfn2), dynamin­related protein 1 (DRP1), voltage­dependent anion­selective channel 1 (VDAC1) and glucose­regulated protein 75 (GRP75). Western blot analysis of total cell extracts and mitochondria isolated from either the cerebral cortex or hippocampus of experimental animals was performed. In addition, Mfn2 was localized intracellularly by laser scanning confocal microscopy. It was demonstrated that 15­min ischemia, or 15­min ischemia followed by 1, 3, 24 or 72 h of reperfusion, was associated with a marked decrease of the Mfn2 protein in mitochondria isolated from the cerebral cortex, but not in hippocampal mitochondria. Moreover, a translocation of the Mfn2 protein to the cytoplasm was documented immediately after global brain ischemia in the neurons of the cerebral cortex by laser scanning confocal microscopy. Mfn2 translocation was followed by decreased expression of Mfn2 during reperfusion. Markedly elevated levels of the VDAC1 protein were also documented in total cell extracts isolated from the hippocampus of rats after 15 min of global brain ischemia followed by 3 h of reperfusion, and from the cerebral cortex of rats after 15 min of global brain ischemia followed by 72 h of reperfusion. The mitochondrial Mfn2 release observed during the early stages of reperfusion may thus represent an important mechanism of mitochondrial dysfunction associated with neuronal dysfunction or death induced by global brain ischemia.

Diabetes-induced abnormalities of mitochondrial function in rat brain cortex: the effect of n-3 fatty acid diet.

Diabetic encephalopathy, a proven complication of diabetes is associated with gradually developing end-organ damage in the CNS increasing the risk of stroke, cognitive dysfunction or Alzheimer's disease. This study investigated the response of rat cortical mitochondria to streptozotocin-induced diabetes and the potential for fish oil emulsion (FOE) to modulate mitochondrial function. Diabetes-induced deregulation of the respiratory chain function as a result of diminished complex I activity (CI) and cytochrome c oxidase hyperactivity was associated with attenuation of antioxidant defense of isolated cortical mitochondria, monitored by SOD activity, the thiol content, the dityrosine and protein-lipid peroxidation adduct formation. A parallel reduction in phosphorylation of the energy marker AMPK has pointed out to disrupted energy homeostasis. Dietary FOE administration partially preserved CI activity, restored AMPK phosphorylation, but was unable to attenuate oxidative stress and prevent the shift toward saturated fatty acids in the cardiolipin composition. Moreover, diabetes has induced alterations in the protein expression of the regulatory COX4 subunit of cytochrome c oxidase, in the inhibitory factor IF1 and ATP5A subunit of F0F1-ATP synthase, in the uncoupling protein UCP4 and supramolecular organization of the respiratory complexes. FOE administration to diabetic rats has partially reversed these alterations. This study suggests diabetes-induced dysfunction of brain cortical mitochondria and its modulation by FOE administration. The intricate diabetic milieu and the n-3 FA nutrigenomic strength, however require further investigations to be able to unequivocally evaluate neuroprotective and adverse effects of FOE supplementation on the diabetic brain function.

Oxidative Stress Markers and Their Dynamic Changes in Patients after Acute Ischemic Stroke.

We have focused on determining the range of oxidative stress biomarkers and their dynamic changes in patients at different time points after the acute ischemic stroke (AIS). 82 patients with AIS were involved in our study and were tested: within 24 h from the onset of the attack (group A); at 7-day follow-up (group B); and at 3-month follow-up (group C). 81 gender and age matched volunteers were used as controls. Stroke patients in group A had significantly higher concentrations of plasma lipid peroxides and urine 8-isoprostanes when compared with controls. Protein carbonyls were not significantly different in any experimental group compared to controls. Antioxidant capacity of plasma was increased only in experimental group C. Activities of superoxide dismutase and catalase were elevated in all three experimental AIS groups compared to controls. Paraoxonase activity was reduced in groups A and B and unchanged in group C when compared to controls. Glutathione peroxide activity was elevated only in group A. Our results suggest that free radical damage is the highest within 24 h after the attack. During the next 3 months oxidative damage to lipids caused by free radicals is reduced due to activated antioxidant system.

Look into brain energy crisis and membrane pathophysiology in ischemia and reperfusion.

In an ischemic environment, brain tissue responds to oxygen deprivation with the initiation of rapid changes in bioenergetic metabolism to ensure ion and metabolic homeostasis. At the same time, the accelerated cleavage of membrane phospholipids changes membrane composition and increases free fatty acid concentration. Phospholipid breakdown also generates specific messengers that participate in signaling cascades that can either promote neuronal protection or cause injury. The net impact of signaling events affects the final outcome of the stroke. While reoxygenation is a life-saving intervention, it can exacerbate brain damage. Although compromised energy metabolism is restored shortly after reperfusion, alterations in membrane phospholipid composition with subsequent accumulation of lipid oxoderivates are neurotoxic, causing oxidative stress and ischemia-reperfusion (IR) injury. Thus, plasma and mitochondrial membranes are the first responders as well as mediators of IR-induced stress signals. In this review, we focus on ischemia-induced changes in brain energy metabolism and membrane functions as the causal agents of cell stress responses upon reoxygenation. The first part of the review deals with the specificities of neuronal bioenergetics during IR and their impact on metabolic processes. The second part is concentrated on involvement of both plasma and mitochondrial membranes in the production of messengers which can modulate neuroprotective pathways or participate in oxidative/electrophilic stress responses. Although the etiology of IR injury is multifactorial, deciphering the role of membrane and membrane-associated processes in brain damage will uncover new therapeutic agents with the ability to stabilize neuronal membranes and modulate their responses in favor of prosurvival pathways.

Possible contribution of proteins of Bcl-2 family in neuronal death following transient global brain ischemia.

Proteins of Bcl-2 family are crucial regulators of intrinsic (mitochondrial) pathway of apoptosis that is implicated among the mechanisms of ischemic neuronal death. Initiation of mitochondrial apoptosis depends on changes of equilibrium between anti-apoptotic and pro-apoptotic proteins of Bcl-2 family as well as on translocation of pro-apoptotic proteins of Bcl-2 family to mitochondria. The aim of this work was to study the effect of transient global brain ischemia on expression and intracellular distribution of proteins of Bcl-2 family in relation to the ischemia-induced changes of ERK and Akt kinase pathways as well as disturbances in ubiquitin proteasome system. Using four vessel occlusion model of transient global brain ischemia, we have shown that both ischemia in duration of 15 min and the same ischemia followed by 1, 3, 24, and 72 h of reperfusion did not affect the levels of either pro-apoptotic (Bad, PUMA, Bim, Bax, Noxa) or anti-apoptotic (Bcl-2, Bcl-xl, Mcl-1) proteins of Bcl-2 family in total cell extracts from rat hippocampus. However, significantly elevated level of Bad protein in the mitochondria isolated from rat hippocampus was observed already 1 h after ischemia and remained elevated 3 and 24 h after ischemia. We did not observe significant changes of the levels of Puma, Bax, Bcl-2, and Bcl-xl in the mitochondria after ischemia and ischemia followed by reperfusion. Our results might indicate possible involvement of Bad translocation to mitochondria in the mechanisms of neuronal death following transient global brain ischemia.

Ischemia-induced inhibition of mitochondrial complex I in rat brain: effect of permeabilization method and electron acceptor.

In this study we have examined the effect of global brain ischemia/reperfusion on biochemical properties of the mitochondrial respiratory complex I (CI) in rat hippocampus and cortex. Since the inner mitochondrial membrane forms the permeability barrier for NADH, the methodology of enzymatic activity determinations employs membrane permeabilization methods. This action affects the basic character of electrostatic and hydrophobic interactions inside the membrane and might influence functional properties of membrane embedded proteins. Therefore we have performed the comparative analysis of two permeabilization methods (sonication, detergent) and their impact on CI enzymatic activities under global brain ischemic-reperfusion conditions. We have observed that ischemia led to significant decrease of CI activities using both permeabilization methods in both brain areas. However, significant differencies in enzymatic activities were registered during reperfusion intervals according to used permeabilization method. We have also tested the effect of electron acceptors (decylubiquinone, potassium ferricyanide, nitrotetrazolium blue) on CI activities during I/R. Based on our results we assume that the critical site where ischemia affects CI activities is electron transfer to electron acceptor. Further, the observed mitochondrial dysfunction was analyzed by means of one and 2-dimensional BN PAGE/SDS PAGE with the focus on 3-nitrotyrosine immunodetection as a marker of oxidative damage to proteins. Add to this, initialization of p53 mitochondrial apoptosis through p53, Bax, Bcl-X(L) proteins and a possible involvement of GRIM-19, the CI structural subunit, in apoptotic processes were also studied.

Leptin, adiponectin and ghrelin, new potential mediators of ischemic stroke.

OBJECTIVES: Fat tissue is an important endocrine organ that produces a number of hormones and cytokines (leptin, adiponectin, resistin, plasminogen activator inhibitor-1, Tumour necrosis factor TNF α) with essential roles in regulation of many physiological functions. METHODS: We targeted implications of adipokines in ischemic stroke patients. Patients with acute stroke were examined (n=145) and the results were compared with the control group (n=68). We have examined potential associations between leptin, adiponectin and ghrelin, and different types of stroke and traditional risk factors. RESULTS: Significantly higher levels of leptin and lower levels of adiponectin and ghrelin were confirmed in the stroke group. The level of leptin in women with stroke was three-times higher than in men, and the leptin levels positively correlated with obesity in both sexes. Ghrelin levels correlated mildly with triglyceride levels, and were dominant in men with cardioembolic stroke. Adiponectin levels were not different between men and women with acute stroke, and correlated with atherothrombotic and lacunar stroke types in men. CONCLUSIONS: Adipokines and ghrelin play an important role in ischemic stroke, but their function in stroke subtypes seems to be different and sex influenced. More research is required to confirm our results.

Mitochondrial complex I in the network of known and unknown facts.

The mitochondrial respiratory chain consists of five multi-subunit complexes embedded in the inner mitochondrial membrane. Complex I is the largest and most complicated proton pump of the respiratory chain encoded by both the mitochondrial and nuclear genomes. In this minireview, attention is given to recent knowledge on the structure, catalytic properties, supramolecular organisation of complex I and its possible role in the triggering of apoptosis.

Ischemia-induced mitochondrial apoptosis is significantly attenuated by ischemic preconditioning.

Ischemic preconditioning (IPC) represents an important adaptation of CNS to sub-lethal ischemia, which results in increased tolerance of CNS to the lethal ischemia. Ischemia-induced mitochondrial apoptosis is considered to be an important event leading to neuronal cell death after cerebral blood flow arrest. In presented study, we have determined the effect of IPC on ischemia/reperfusion-induced mitochondrial apoptosis. Global brain ischemia was induced by permanent occlusion of vertebral arteries and temporal occlusion of carotid arteries for 15 min. Rats were preconditioned by 5 min of sub-lethal ischemia and 2 days later 15 min of lethal ischemia was induced. With respect to mitochondrial apoptosis initiation, translocation of p53 to mitochondria was observed in hippocampus but not in cerebral cortex. However, level of both apoptotic bax and anti-apoptotic bcl-xl in both hippocampal and cortical mitochondria was unchanged after global brain ischemia. Detection of genomic DNA fragmentation as well as Fluoro-Jade C staining showed that ischemia induces apoptosis in vulnerable CA1 layer of rat hippocampus. IPC abolished completely ischemia-induced translocation of p53 to mitochondria and had significant protective effect on ischemia-induced DNA fragmentation. In addition, significant decrease of Fluoro-Jade C positive cells was observed as well. Our results indicate that IPC abolished almost completely both initiation and execution of mitochondrial apoptosis induced by global brain ischemia.

Mitochondrial calcium transport and mitochondrial dysfunction after global brain ischemia in rat hippocampus.

Here we report effect of ischemia-reperfusion on mitochondrial Ca2+ uptake and activity of complexes I and IV in rat hippocampus. By performing 4-vessel occlusion model of global brain ischemia, we observed that 15 min ischemia led to significant decrease of mitochondrial capacity to accumulate Ca2+ to 80.8% of control whereas rate of Ca2+ uptake was not significantly changed. Reperfusion did not significantly change mitochondrial Ca2+ transport. Ischemia induced progressive inhibition of complex I, affecting final electron transfer to decylubiquinone. Minimal activity of complex I was observed 24 h after ischemia (63% of control). Inhibition of complex IV activity to 80.6% of control was observed 1 h after ischemia. To explain the discrepancy between impact of ischemia on rate of Ca2+ uptake and activities of both complexes, we performed titration experiments to study relationship between inhibition of particular complex and generation of mitochondrial transmembrane potential (DeltaPsi(m)). Generation of a threshold curves showed that complex I and IV activities must be decreased by approximately 40, and 60%, respectively, before significant decline in DeltaPsi(m) was documented. Thus, mitochondrial Ca2+ uptake was not significantly affected by ischemia-reperfusion, apparently due to excess capacity of the complexes I and IV. Inhibition of complex I is favourable of reactive oxygen species (ROS) generation. Maximal oxidative modification of membrane proteins was documented 1 h after ischemia. Although enhanced formation of ROS might contribute to neuronal injury, depressed activities of complex I and IV together with unaltered rate of Ca2+ uptake are conditions favourable of initiation of other cell degenerative pathways like opening of mitochondrial permeability transition pore or apoptosis initiation, and might represent important mechanism of ischemic damage to neurones.

Cross-talk of intracellular calcium stores in the response to neuronal ischemia and ischemic tolerance.

Ischemic/reperfusion brain injury (IRI) is a very severe event with the multiple etiopathogenesis. Ischemic preconditioning (IPC) is an important phenomenon of adaptation of CNS to subsequent ischemia. An altered cross-talk between intracellular calcium stores is presumed in the mechanisms of ischemic damage/protection. We show here that IRI leads to the inhibition of mitochondrial respiratory complexes I and IV, however due to the excess of their capacities, the mitochondrial Ca(2+) uptake rate is not significantly depressed. IPC acts at the level of both initiation and execution of IRI-induced mitochondrial apoptosis and protects from IRI-associated changes in integrity of mitochondrial membranes. IPC also activates inhibition of p53 translocation to mitochondria. Inhibition of the mitochondrial p53 pathway might thus provide a potentially important mechanism of neuronal survival after ischemic brain damage. In addition, IRI initiates a time dependent differences in endoplasmic reticular (ER) gene expression of the key UPR proteins at both the mRNA and protein levels. Moreover, gene expression of the UPR proteins is affected by preischemic treatment by the increased expression of Ca(2+) binding protein: GRP 78 and transcriptional factor ATF6 in reperfusion times. Thus, IPC exerts a role in the attenuation of ER stress response, which might be involved in the neuroprotective phenomenon of ischemic tolerance. Hippocampal cells respond to the IRI by the specific expression pattern of the secretory pathways Ca(2+) pump (SPCA1) and this pattern is affected by preischemic challenge. IPC also incompletely suppresses lipo- and protein oxidation of hippocampal membranes and leads to partial recovery of the ischemic-induced depression of SPCA activity. The data suggests the correlation of SPCA function with the role of secretory pathways (Golgi apparatus) in response to preischemic challenge. Documented functional alterations of mitochondria, ER and Golgi apparatus put light into the understanding of cross-talk between intracellular Ca(2+) stores in cerebral ischemia and ischemic tolerance and might suggest for possible targets of future therapeutic interventions to enhance recovery after stroke.