Estradiol-induced protection against ischemia-induced heart mitochondrial damage and caspase activation is mediated by protein kinase G

We have previously reported that estradiol can protect heart mitochondria from the ischemia-induced mitochondrial permeability transition pore-related release of cytochrome c and subsequent apoptosis. In this study we investigated whether the effect of 17-beta-estradiol on ischemia-induced mitochondrial dysfunctions and apoptosis is mediated by activation of signaling protein kinases in a Langendorff-perfused rat heart model of stop-flow ischemia. We found that pre-perfusion of non-ischemic hearts with 100 nM estradiol increased the resistance of subsequently isolated mitochondria to the calcium-induced opening of mitochondrial permeability transition pore and this was mediated by protein kinase G. Loading of the hearts with estradiol prevented ischemia-induced loss of cytochrome c from mitochondria and respiratory inhibition and these effects were reversed in the presence of the inhibitor of Akt kinase, NO synthase inhibitor L-NAME, guanylyl cyclase inhibitor ODQ and protein kinase G inhibitor KT5823. Estradiol prevented ischemia-induced activation of caspases and this was also reversed by KT5823. These findings suggest that estradiol may protect the heart against ischemia-induced injury activating the signaling cascade which involves Akt kinase, NO synthase, guanylyl cyclase and protein kinase G, and results in blockage of mitochondrial permeability transition pore-induced release of cytochrome c from mitochondria, respiratory inhibition and activation of caspases.     

Oxygen glucose deprivation causes mitochondrial dysfunction in cultivated rat hippocampal slices: Protective effects of CsA,its immunosuppressive congener [D-Ser]8CsA,the novel non-immunosuppressive cyclosporin derivative Cs9, and the NMDA receptor antagonist MK 801

We have introduced a sensitive method for studying oxygen/glucose deprivation (OGD)-induced mitochondrial alterations in homogenates of organotypic hippocampal slice cultures (slices) by high-resolution respirometry. Using this approach, we tested the neuroprotective potential of the novel non-immunosuppressive cyclosporin (CsA) derivative Cs9 in comparison with CsA, the immunosuppressive CsA analog [D-Ser]⁸CsA, and MK 801, a N-methyl-d-aspartate (NMDA) receptor antagonist. OGD/reperfusion reduced the glutamate/malate dependent (and protein-related) state 3 respiration to 30% of its value under control conditions. All of the above drugs reversed this effect, with an increase to > 88% of the value for control slices not exposed to OGD. We conclude that Cs9, [D-Ser]⁸CsA, and MK 801, despite their different modes of action, protect mitochondria from OGD-induced damage.     

Correction to: Phloroglucinols from Myrtaceae: attractive targets for structural characterization,biological properties and synthetic procedures

Phytochemistry Reviews - The original version of this article was missing an equal contribution statement.     

Chemotypes of Achillea millefolium transferred from 14 different locations in Lithuania to the controlled environment

The composition of essential oils hydrodistilled from 19 samples of inflorescences and leaves of Achillea millefolium L. plants, which were transferred from 14 natural habitats in Lithuania to the field collection, is reported. Total content of oil was 0.15–0.55% in inflorescences and 0.06–0.19% (v/w) in leaves. In total 117 compounds were identified positively or tentatively. Data obtained clearly indicate the presence of a remarkable chemical polymorphism within the population of A. millefolium in Lithuania. The content of the major constituents in the oils from inflorescences varied in the following ranges: β-pinene, 0.33–62.29%; β-myrcene, 0.05–69.76%; α-phelandrene, 0.13–29.96%; 1,8-cineole, 2.30–21.57%; and chamazulene, 0.08–30.70%. According to the major components the essential oils' six chemotypes of A. millefolium were defined.     

Extramitochondrial Ca2+ in the Nanomolar Range Regulates Glutamate-Dependent Oxidative Phosphorylation on Demand

We present unexpected and novel results revealing that glutamate-dependent oxidative phosphorylation (OXPHOS) of brain mitochondria is exclusively and efficiently activated by extramitochondrial Ca²⁺ in physiological concentration ranges (S_0.5 = 360 nM Ca²⁺). This regulation was not affected by RR, an inhibitor of the mitochondrial Ca²⁺ uniporter. Active respiration is regulated by glutamate supply to mitochondria via aralar, a mitochondrial glutamate/aspartate carrier with regulatory Ca²⁺-binding sites in the mitochondrial intermembrane space providing full access to cytosolic Ca²⁺. At micromolar concentrations, Ca²⁺ can also enter the intramitochondrial matrix and activate specific dehydrogenases. However, the latter mechanism is less efficient than extramitochondrial Ca²⁺ regulation of respiration/OXPHOS via aralar. These results imply a new mode of glutamate-dependent OXPHOS regulation as a demand-driven regulation of mitochondrial function. This regulation involves the mitochondrial glutamate/aspartate carrier aralar which controls mitochondrial substrate supply according to the level of extramitochondrial Ca²⁺.     

Effects of itaconic acid on neuronal viability and brain mitochondrial functions

Recent studies have identified that under stimulation by bacterial lipopolysaccharide mammalian macrophages produce itaconic acid. Yet, it is unknown whether itaconate has any effect on viability of brain cells. Here we used extracellularly added itaconate to investigate its effects on viability of cerebellar granule cells (CGC) in cultures and respiratory functions of these cells and isolated brain mitochondria. We found that 3–5 mM itaconate had no effect on the viability of neurons, but 10 mM itaconate was toxic and induced neuronal apoptosis. Removal of itaconate after 24 h incubation resulted in further decrease in viability and number of neurons. Respiration of intact neurons was not affected by itaconate, but permeabilized cells as well as isolated brain mitochondria demonstrated decreased rates of respiration in the presence of itaconate. Using isolated adult rat brain mitochondria we found that itaconate decreased mitochondrial phosphorylating respiration, mitochondrial calcium retention capacity, production of reactive oxygen species with Complex I and Complex II substrates as well as inhibition of Complex I, Complex IV and ATP synthase. In conclusion, the results suggest that itaconic acid at millimolar concentrations affects mitochondrial functions and viability of neurons.

     

The regulation of OXPHOS by extramitochondrial calcium

Despite extensive research, the regulation of mitochondrial function is still not understood completely. Ample evidence shows that cytosolic Ca²⁺ has a strategic task in co-ordinating the cellular work load and the regeneration of ATP by mitochondria. Currently, the paradigmatic view is that Ca_cyt²⁺ taken up by the Ca²⁺ uniporter activates the matrix enzymes pyruvate dehydrogenase, α-ketoglutarate dehydrogenase and isocitrate dehydrogenase. However, we have recently found that Ca²⁺ regulates the glutamate-dependent state 3 respiration by the supply of glutamate to mitochondria via aralar, a mitochondrial glutamate/aspartate carrier. Since this activation is not affected by ruthenium red, glutamate transport into mitochondria is controlled exclusively by extramitochondrial Ca²⁺. Therefore, this discovery shows that besides intramitochondrial also extramitochondrial Ca²⁺ regulates oxidative phosphorylation. This new mechanism acts as a mitochondrial “gas pedal”, supplying the OXPHOS with substrate on demand. These results are in line with recent findings of Satrustegui and Palmieri showing that aralar as part of the malate–aspartate shuttle is involved in the Ca²⁺-dependent transport of reducing hydrogen equivalents (from NADH) into mitochondria. This review summarises results and evidence as well as hypothetical interpretations of data supporting the view that at the surface of mitochondria different regulatory Ca²⁺-binding sites exist and can contribute to cellular energy homeostasis. Moreover, on the basis of our own data, we propose that these surface Ca²⁺-binding sites may act as targets for neurotoxic proteins such as mutated huntingtin and others. The binding of these proteins to Ca²⁺-binding sites can impair the regulation by Ca²⁺, causing energetic depression and neurodegeneration.     

Nitric oxide protects the heart from ischemia-induced apoptosis and mitochondrial damage via protein kinase G mediated blockage of permeability transition and cytochrome c release

Background  

Heart ischemia can rapidly induce apoptosis and mitochondrial dysfunction via mitochondrial permeability transition-induced cytochrome c release. We tested whether nitric oxide (NO) can block this damage in isolated rat heart, and, if so, by what mechanisms.