Anthony J.A. Molina

Fission and selective fusion govern mitochondrial segregation and elimination by autophagy

Accumulation of depolarized mitochondria within β‐cells has been associated with oxidative damage and development of diabetes. To determine the source and fate of depolarized mitochondria, individual mitochondria were photolabeled and tracked through fusion and fission. Mitochondria were found to go through frequent cycles of fusion and fission in a ‘kiss and run’ pattern. Fission events often generated uneven daughter units: one daughter exhibited increased membrane potential (Δψm) and a high probability of subsequent fusion, while the other had decreased membrane potential and a reduced probability for a fusion event. Together, this pattern generated a subpopulation of non‐fusing mitochondria that were found to have reduced Δψm and decreased levels of the fusion protein OPA1. Inhibition of the fission machinery through DRP1K38A or FIS1 RNAi decreased mitochondrial autophagy and resulted in the accumulation of oxidized mitochondrial proteins, reduced respiration and impaired insulin secretion. Pulse chase and arrest of autophagy at the pre‐proteolysis stage reveal that before autophagy mitochondria lose Δψm and OPA1, and that overexpression of OPA1 decreases mitochondrial autophagy. Together, these findings suggest that fission followed by selective fusion segregates dysfunctional mitochondria and permits their removal by autophagy.

Mitochondrial Networking Protects β-Cells From Nutrient-Induced Apoptosis

OBJECTIVE Previous studies have reported that β-cell mitochondria exist as discrete organelles that exhibit heterogeneous bioenergetic capacity. To date, networking activity, and its role in mediating β-cell mitochondrial morphology and function, remains unclear. In this article, we investigate β-cell mitochondrial fusion and fission in detail and report alterations in response to various combinations of nutrients. RESEARCH DESIGN AND METHODS Using matrix-targeted photoactivatable green fluorescent protein, mitochondria were tagged and tracked in β-cells within intact islets, as isolated cells and as cell lines, revealing frequent fusion and fission events. Manipulations of key mitochondrial dynamics proteins OPA1, DRP1, and Fis1 were tested for their role in β-cell mitochondrial morphology. The combined effects of free fatty acid and glucose on β-cell survival, function, and mitochondrial morphology were explored with relation to alterations in fusion and fission capacity. RESULTS β-Cell mitochondria are constantly involved in fusion and fission activity that underlies the overall morphology of the organelle. We find that networking activity among mitochondria is capable of distributing a localized green fluorescent protein signal throughout an isolated β-cell, a β-cell within an islet, and an INS1 cell. Under noxious conditions, we find that β-cell mitochondria become fragmented and lose their ability to undergo fusion. Interestingly, manipulations that shift the dynamic balance to favor fusion are able to prevent mitochondrial fragmentation, maintain mitochondrial dynamics, and prevent apoptosis. CONCLUSIONS These data suggest that alterations in mitochondrial fusion and fission play a critical role in nutrient-induced β-cell apoptosis and may be involved in the pathophysiology of type 2 diabetes.

High Glucose Disrupts Mitochondrial Morphology in Retinal Endothelial Cells : Implications for Diabetic Retinopathy

Mitochondrial dysfunction has been implicated in diabetic complications; however, it is unknown whether hyperglycemia affects mitochondrial morphology and metabolic capacity during development of diabetic retinopathy. We investigated high glucose (HG) effects on mitochondrial morphology, membrane potential heterogeneity, cellular oxygen consumption, extracellular acidification, cytochrome c release, and apoptosis in retinal endothelial cells. Rat retinal endothelial cells grown in normal (5 mmol/L) or HG (30 mmol/L) medium and double-stained with MitoTracker Green and tetramethylrhodamine-ethyl-ester-perchlorate were examined live with confocal microscopy. Images were analyzed for mitochondrial shape change using Form Factor and Aspect Ratio values, and membrane potential heterogeneity, using deviation of fluorescence intensity values. Rat retinal endothelial cells grown in normal or HG medium were analyzed for transient changes in oxygen consumption and extracellular acidification using an XF-24 flux analyzer, cytochrome c release by Western blot, and apoptosis by terminal deoxynucleotidyl transferase-mediated dUTP nick-end labeling assay. Rat retinal endothelial cells grown in HG medium exhibited increased mitochondrial fragmentation concurrent with membrane potential heterogeneity. Metabolic analysis showed increased extracellular acidification in HG with reduced steady state/maximal oxygen consumption. Cytochrome c and terminal deoxynucleotidyl transferase-mediated dUTP nick-end labeling-positive cells were also increased in HG. Thus, HG-induced mitochondrial fragmentation with concomitant increase in membrane potential heterogeneity, reduced oxygen consumption, and cytochrome c release may underlie apoptosis of retinal endothelial cells as seen in diabetic retinopathy.

High Glucose Induces Mitochondrial Morphology and Metabolic Changes in Retinal Pericytes

PURPOSEnMitochondrial dysfunction is known to play a role in retinal vascular cell loss, a prominent lesion of diabetic retinopathy. High glucose (HG) has been reported to induce mitochondrial fragmentation and dysfunction in retinal endothelial cells, contributing to apoptosis. In this study, the effects of HG on mitochondrial morphology, membrane potential, and metabolic changes and whether they could contribute to HG-induced apoptosis in retinal pericytes were investigated.nnnMETHODSnBovine retinal pericytes (BRPs) were grown in normal or HG medium for 7 days. Both sets of cells were double stained with mitochondrial membrane potential-independent dye and tetramethylrhodamine-ethyl-ester-perchlorate (TMRE) and imaged by confocal microscopy. The images were analyzed for average mitochondria shape, by using form factor and aspect ratio values, and membrane potential changes, by using the ratio between the red and green dye. BRPs grown in normal or HG medium were analyzed for transient changes in oxygen consumption and extracellular acidification with a flux analyzer and apoptosis by TUNEL assay.nnnRESULTSnBRPs grown in HG media exhibited significant fragmentation of mitochondria and increased membrane potential heterogeneity compared with the BRPs grown in normal medium. Concomitantly, BRPs grown in HG showed reduced steady state and maximum oxygen consumption and reduced extracellular acidification. Number of TUNEL-positive pericytes was increased in HG condition as well.nnnCONCLUSIONSnIn HG condition, mitochondria of retinal pericytes display significant fragmentation, metabolic dysfunction, and reduced extracellular acidification. The detrimental effects of HG on mitochondrial function and cellular metabolism could play a role in the accelerated apoptosis associated with the retinal pericytes in diabetic retinopathy.

Modulation of Extracellular Proton Fluxes from Retinal Horizontal Cells of the Catfish by Depolarization and Glutamate

Self-referencing H+-selective microelectrodes were used to measure extracellular proton fluxes from cone-driven horizontal cells isolated from the retina of the catfish (Ictalurus punctatus). The neurotransmitter glutamate induced an alkalinization of the area adjacent to the external face of the cell membrane. The effect of glutamate occurred regardless of whether the external solution was buffered with 1 mM HEPES, 3 mM phosphate, or 24 mM bicarbonate. The AMPA/kainate receptor agonist kainate and the NMDA receptor agonist N-methyl-d-aspartate both mimicked the effect of glutamate. The effect of kainate on proton flux was inhibited by the AMPA/kainate receptor blocker CNQX, and the effect of NMDA was abolished by the NMDA receptor antagonist DAP-5. Metabotropic glutamate receptor agonists produced no alteration in proton fluxes from horizontal cells. Depolarization of cells either by increasing extracellular potassium or directly by voltage clamp also produced an alkalinization adjacent to the cell membrane. The effects of depolarization on proton flux were blocked by 10 μM nifedipine, an inhibitor of L-type calcium channels. The plasmalemma Ca2+/H+ ATPase (PMCA) blocker 5(6)-carboxyeosin also significantly reduced proton flux modulation by glutamate. Our results are consistent with the hypothesis that glutamate-induced extracellular alkalinizations arise from activation of the PMCA pump following increased intracellular calcium entry into cells. This process might help to relieve suppression of photoreceptor neurotransmitter release that results from exocytosed protons from photoreceptor synaptic terminals. Our findings argue strongly against the hypothesis that protons released by horizontal cells act as the inhibitory feedback neurotransmitter that creates the surround portion of the receptive fields of retinal neurons.

Neurotransmitter modulation of extracellular H+ fluxes from isolated retinal horizontal cells of the skate

Self‐referencing H+‐selective microelectrodes were used to measure extracellular H+ fluxes from horizontal cells isolated from the skate retina. A standing H+ flux was detected from quiescent cells, indicating a higher concentration of free hydrogen ions near the extracellular surface of the cell as compared to the surrounding solution. The standing H+ flux was reduced by removal of extracellular sodium or application of 5‐(N‐ethyl‐N‐isopropyl) amiloride (EIPA), suggesting activity of a Na+–H+ exchanger. Glutamate decreased H+ flux, lowering the concentration of free hydrogen ions around the cell. AMPA/kainate receptor agonists mimicked the response, and the AMPA/kainate receptor antagonist 6‐cyano‐7‐nitroquinoxaline‐2,3‐dione (CNQX) eliminated the effects of glutamate and kainate. Metabotropic glutamate agonists were without effect. Glutamate‐induced alterations in H+ flux required extracellular calcium, and were abolished when cells were bathed in an alkaline Ringer solution. Increasing intracellular calcium by photolysis of the caged calcium compound NP‐EGTA also altered extracellular H+ flux. Immunocytochemical localization of the plasmalemma Ca2+–H+‐ATPase (PMCA pump) revealed intense labelling within the outer plexiform layer and on isolated horizontal cells. Our results suggest that glutamate modulation of H+ flux arises from calcium entry into cells with subsequent activation of the plasmalemma Ca2+–H+‐ATPase. These neurotransmitter‐induced changes in extracellular pH have the potential to play a modulatory role in synaptic processing in the outer retina. However, our findings argue against the hypothesis that hydrogen ions released by horizontal cells normally act as the inhibitory feedback neurotransmitter onto photoreceptor synaptic terminals to create the surround portion of the centre‐surround receptive fields of retinal neurones.

Chapter 16 Monitoring Mitochondrial Dynamics with Photoactivateable Green Fluorescent Protein

Mitochondria are dynamic organelles that undergo continuous cycles of fusion and fission. Monitoring and quantification of mitochondrial dynamics has proved to be challenging because these processes are distinctly different from movement and apposition. While the majority of contact events do not lead to fusion, fission can occur without translocation, leaving the two mitochondria juxtaposed. The advent of photoactivatable fluorescent proteins has enabled researchers to distinguish mitochondrial fusion and fission. These genetically encoded fluorophores can be targeted to the mitochondrial compartments of interest to visualize how these intermix and segregate between dynamic mitochondria over time. The PAGFPmt-based mitochondrial dynamics assay has proved to be a powerful technique for revealing the treatments and cellular processes that affect fusion and fission. By using this technique in combination with other parameters, such as measurements of mitochondrial membrane potential, we have begun to understand the processes that control fusion and fission as well as the significance of mitochondrial dynamics.

Hydrogen ion fluxes from isolated retinal horizontal cells: modulation by glutamate

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Intracellular Release of Caged Calcium in Skate Horizontal Cells Using Fine Optical Fibers

Horizontal cells are second order retinal neurons that receive direct input from photoreceptors and are involved in establishing a number of key features of visual perception. These cells mediate the formation of the inhibitory surround portion of the classic center-surround receptive fi elds of retinal neurons (1). The centersurround receptive fi elds are important for enhancing the contrast of visual objects and are also involved in color perception. The molecular mechanisms by which horizontal cells send lateral inhibitory signals to photoreceptors and bipolar cells are still under debate, but protons released from horizontal cells have been hypothesized to alter the fl ow of visual information within the outer retina (2). Indeed, small changes in extracellular pH can dramatically alter neural signals within the retina, in part because photoreceptor calcium channels are highly sensitive to protons. When protons bind to photoreceptor calcium channels, the voltage activation range of the channels shifts to more depolarized potentials and the overall conductance of the cell to calcium is reduced, which signifi cantly reduces neurotransmitter release (3). Our previous work has shown that glutamate, the neurotransmitter released by photoreceptors onto horizontal cells, modulates the fl ux of hydrogen ions from skate retinal horizontal cells (4). Glutamateinduced changes in H fl ux depend on the presence of extracellular calcium and likely refl ect the activation of plasma membrane calcium/H ATPases. These transporters extrude intracellular cal cium in exchange for extracellular hydrogen ions, decreasing the concentration of protons at the extracellular face of the horizontal cells (5).