Interactions between Electron and Proton Currents in Excised Patches from Human Eosinophils

The NADPH–oxidase is a plasma membrane enzyme complex that enables phagocytes to generate superoxide in order to kill invading pathogens, a critical step in the host defense against infections. The oxidase transfers electrons from cytosolic NADPH to extracellular oxygen, a process that requires concomitant H+ extrusion through depolarization-activated H+ channels. Whether H+ fluxes are mediated by the oxidase itself is controversial, but there is a general agreement that the oxidase and H+ channel are intimately connected. Oxidase activation evokes profound changes in whole-cell H+ current (IH), causing an approximately −40-mV shift in the activation threshold that leads to the appearance of inward IH. To further explore the relationship between the oxidase and proton channel, we performed voltage-clamp experiments on inside-out patches from both resting and phorbol-12-myristate-13-acetate (PMA)-activated human eosinophils. Proton currents from resting cells displayed slow voltage-dependent activation, long-term stability, and were blocked by micromolar internal [Zn2+]. IH from PMA-treated cells activated faster and at lower voltages, enabling sustained H+ influx, but ran down within minutes, regaining the current properties of nonactivated cells. Bath application of NADPH to patches excised from PMA-treated cells evoked electron currents (Ie), which also ran down within minutes and were blocked by diphenylene iodonium (DPI). Run-down of both IH and Ie was delayed, and sometimes prevented, by cytosolic ATP and GTP-γ-S. A good correlation was observed between the amplitude of Ie and both inward and outward IH when a stable driving force for e− was imposed. Combined application of NADPH and DPI reduced the inward IH amplitude, even in the absence of concomitant oxidase activity. The strict correlation between Ie and IH amplitudes and the sensitivity of IH to oxidase-specific agents suggest that the proton channel is either part of the oxidase complex or linked by a membrane-limited mediator

Extramitochondrial OPA1 and adrenocortical function

We have previously described that silencing of the mitochondrial protein OPA1 enhances mitochondrial 27 Ca2+ signaling and aldosterone production in H295R adrenocortical cells. Since extramitochondrial OPA1 28 (emOPA1) was reported to facilitate cAMP-induced lipolysis, we hypothesized that emOPA1, via the 29 enhanced hydrolysis of cholesterol esters, augments aldosterone production in H295R cells. A few 30 OPA1 immunopositive spots were detected in �40% of the cells. In cell fractionation studies OPA1/COX 31 IV (mitochondrial marker) ratio in the post-mitochondrial fractions was an order of magnitude higher 32 than that in the mitochondrial fraction. The ratio of long to short OPA1 isoforms was lower in post-mito- 33 chondrial than in mitochondrial fractions. Knockdown of OPA1 failed to reduce db-cAMP-induced phos- 34 phorylation of hormone-sensitive lipase (HSL), Ca2+ signaling and aldosterone secretion. In conclusion, 35 OPA1 could be detected in the post-mitochondrial fractions, nevertheless, OPA1 did not interfere with 36 the cAMP – PKA – HSL mediated activation of aldosterone secretio

Calcium-dependent mitochondrial cAMP production enhances aldosterone secretion

Glomerulosa cells secrete aldosterone in response to agonists coupled to Ca2+ increases such as angiotensin II and corticotrophin, coupled to a cAMP dependent pathway. A recently recognized interaction between Ca2+ and cAMP is the Ca2+-induced cAMP formation in the mitochondrial matrix. Here we describe that soluble adenylyl cyclase (sAC) is expressed in H295R adrenocortical cells. Mitochondrial cAMP formation, monitored with a mitochondria-targeted fluorescent sensor (4mtH30), is enhanced by HCO3 - and the Ca2+ mobilizing agonist angiotensin II. The effect of angiotensin II is inhibited by 2-OHE, an inhibitor of sAC, and by RNA interference of sAC, but enhanced by an inhibitor of phosphodiesterase PDE2A. Heterologous expression of the Ca2+ binding protein S100G within the mitochondrial matrix attenuates angiotensin II-induced mitochondrial cAMP formation. Inhibition and knockdown of sAC significantly reduce angiotensin II-induced aldosterone production. These data provide the first evidence for a cell-specific functional role of mitochondrial cAMP. © 2015 Elsevier Ireland Ltd

Elektron transzfer rendszerek élettani szerepe = The physiological role of electron transfer systems

Fagocitákban leírtuk a NADPH oxidázt szabályozó két különböző GTPáz aktiváló fehérje szabályozását és a kísérő K+ transzport baktérium ölő hatását. Agyi mitokondriumokban (mito) a légzési lánc I. komplexének szubsztrátjai membránpotenciál (Em) függően reaktív oxigénszármazékot (ROS) képeznek. Az alfa-glicerofoszfát (aGP) ROS-t képez az I. komplexen és az aGP-dehidrogenáz enzimen, utóbbit a Ca2+ aktivája. Idegvégződésekben a mito ROS képzését az Em nem befolyásolja. A mito-k elektromos szincíciumot képeznek, de a Ca2+ diffúziója korlátozott. Alacsony O2.- szint a Ca2+ -mobilizáló agonista Ca2+ jel képző hatását glomerulóza sejtben gátolja. A ROS támadáspontja a belső raktárból történő Ca2+ felszabadulás. UV hatására a mito Ca2+ felvétele is csökkent. Angiotenzin II -vel ingerelt H295R sejtben a mito Ca2+ jel képzés sebessége a mito és az endoplazmás retikulum (ER) közelségével korrelál. A p38 MAPK és az újtípusú PKC izoformák egyidejű gátlása a Ca2+ jelnek a citoszolból a mito-ba történő áttevődését gátolja és a fenti korrelációt megszünteti. Az ER lumenében a tiol/diszulfid rendszertől elkülönülő NAD(P)+/NAD(P)H rendszer működik. Redox állapotát a glukóz-6-foszfát transzporter és az intraluminális oxidoreduktázok határozzák meg. A redukált állapot fenntartása szükséges a glukokortikoidok prereceptoriális aktiválásához, s egyes sejtekben antiapoptotikus hatású. Jellemeztük az ER szulfát transzporterét, valamint a transzlokon peptid csatorna anion permeabilitását. | We described in phagocytes the regulation of two GTPase activating proteins, terminating the activity of plasmalemmal NADPH oxidase and the role of K+ movements in bacterial killing. In brain mitochondria complex I dependent substrates show a membrane potential (Em) dependent reactive oxygen species (ROS) formation. ROS production by alpha-glycerophosphate (aGP) occured at complex I and on the aGP-dehydrogenase enzyme. The latter is activited by Ca2+. Mitochondria form an electric syntitium but the diffusion of Ca2+ is limited. In glomerulosa cells, at low [O2.-] angiotensin-induced Ca2+ signalling is attenuated, the site of ROS action is Ca2+ release from the internal stores. The rate of mitochondrial Ca2+ uptake in angiotensin-stimulated cells correlates with the vicinity of the mitochondrion and the endoplasmic reticulum (ER). Simultaneous activation of p38 MAPK and the novel isoforms of PKC attenuates the transfer of cytosolic Ca2+ signal into the mitochondria and abolishes this correlation. In the ER we observed a novel NAD(P)+/NAD(P)H system different from the thiol/disulphide system. Its reduced state is tuned by the glucose-6-phosphate transporter and the luminal oxidoreductases and is required for the prereceptorial activation of glucocorticoids. We have characterized the sulphate transport in the ER, and the contribution of the translocon peptide channel to the membrane permeation of small anions

Mitochondrial Ca uptake correlates with the severity of the symptoms in autosomal dominant optic atrophy.

The most frequent form of hereditary blindness, autosomal dominant optic atrophy (ADOA), is caused by the mutation of the mitochondrial protein Opa1 and the ensuing degeneration of retinal ganglion cells. Previously we found that knockdown of OPA1 enhanced mitochondrial Ca2+ uptake (Fulop et al., 2011). Therefore we studied mitochondrial Ca2+ metabolism in fibroblasts obtained from members of an ADOA family. Gene sequencing revealed heterozygosity for a splice site mutation (c. 984+1G>A) in intron 9 of the OPA1 gene. ADOA cells showed a higher rate of apoptosis than control cells and their mitochondria displayed increased fragmentation when forced to oxidative metabolism. The ophthalmological parameters critical fusion frequency and ganglion cell-inner plexiform layer thickness were inversely correlated to the evoked mitochondrial Ca2+ signals. The present data indicate that enhanced mitochondrial Ca2+ uptake is a pathogenetic factor in the progress of ADOA

The Effect of OPA1 on Mitochondrial Ca2+ Signaling

The dynamin-related GTPase protein OPA1, localized in the intermembrane space and tethered to the inner membrane of mitochondria, participates in the fusion of these organelles. Its mutation is the most prevalent cause of Autosomal Dominant Optic Atrophy. OPA1 controls the diameter of the junctions between the boundary part of the inner membrane and the membrane of cristae and reduces the diffusibility of cytochrome c through these junctions. We postulated that if significant Ca2+ uptake into the matrix occurs from the lumen of the cristae, reduced expression of OPA1 would increase the access of Ca2+ to the transporters in the crista membrane and thus would enhance Ca2+ uptake. In intact H295R adrenocortical and HeLa cells cytosolic Ca2+ signals evoked with K+ and histamine, respectively, were transferred into the mitochondria. The rate and amplitude of mitochondrial [Ca2+] rise (followed with confocal laser scanning microscopy and FRET measurements with fluorescent wide-field microscopy) were increased after knockdown of OPA1, as compared with cells transfected with control RNA or mitofusin1 siRNA. Ca2+ uptake was enhanced despite reduced mitochondrial membrane potential. In permeabilized cells the rate of Ca2+ uptake by depolarized mitochondria was also increased in OPA1-silenced cells. The participation of Na+/Ca2+ and Ca2+/H+ antiporters in this transport process is indicated by pharmacological data. Altogether, our observations reveal the significance of OPA1 in the control of mitochondrial Ca2+ metabolism

The Role of Mitochondria in the Activation/Maintenance of SOCE: Store-Operated Ca2+ Entry and Mitochondria.

Mitochondria extensively modify virtually all cellular Ca2+ transport processes, and store-operated Ca2+ entry (SOCE) is no exception to this rule. The interaction between SOCE and mitochondria is complex and reciprocal, substantially altering and, ultimately, fine-tuning both capacitative Ca2+ influx and mitochondrial function. Mitochondria, owing to their considerable Ca2+ accumulation ability, extensively buffer the cytosolic Ca2+ in their vicinity. In turn, the accumulated ion is released back into the neighboring cytosol during net Ca2+ efflux. Since store depletion itself and the successive SOCE are both Ca2+-regulated phenomena, mitochondrial Ca2+ handling may have wide-ranging effects on capacitative Ca2+ influx at any given time. In addition, mitochondria may also produce or consume soluble factors known to affect store-operated channels. On the other hand, Ca2+ entering the cell during SOCE is sensed by mitochondria, and the ensuing mitochondrial Ca2+ uptake boosts mitochondrial energy metabolism and, if Ca2+ overload occurs, may even lead to apoptosis or cell death. In several cell types, mitochondria seem to be sterically excluded from the confined space that forms between the plasma membrane (PM) and endoplasmic reticulum (ER) during SOCE. This implies that high-Ca2+ microdomains comparable to those observed between the ER and mitochondria do not form here. In the following chapter, the above aspects of the many-sided SOCE-mitochondrion interplay will be discussed in greater detail