Allen Kaasik

PGC-1{alpha} and PGC-1{beta} regulate mitochondrial density in neurons.

Recent studies indicate that regulation of cellular oxidative capacity through enhancing mitochondrial biogenesis may be beneficial for neuronal recovery and survival in human neurodegenerative disorders. The peroxisome proliferator-activated receptor γ coactivator-1α (PGC-1α) has been shown to be a master regulator of mitochondrial biogenesis and cellular energy metabolism in muscle and liver. The aim of our study was to establish whether PGC-1α and PGC-1β control mitochondrial density also in neurons and if these coactivators could be up-regulated by deacetylation. The results demonstrate that PGC-1α and PGC-1β control mitochondrial capacity in an additive and independent manner. This effect was observed in all studied subtypes of neurons, in cortical, midbrain, and cerebellar granule neurons. We also observed that endogenous neuronal PGC-1α but not PGC-1β could be activated through its repressor domain by suppressing it. Results demonstrate also that overexpression of SIRT1 deacetylase or suppression of GCN5 acetyltransferase activates transcriptional activity of PGC-1α in neurons and increases mitochondrial density. These effects were mediated exclusively via PGC-1α, since overexpression of SIRT1 or suppression of GCN5 was ineffective where PGC-1α was suppressed by short hairpin RNA. Moreover, the results demonstrate that overexpression of PGC-1β or PGC-1α or activation of the latter by SIRT1 protected neurons from mutant α-synuclein- or mutant huntingtin-induced mitochondrial loss. These evidences demonstrate that activation or overexpression of the PGC-1 family of coactivators could be used to compensate for neuronal mitochondrial loss and suggest that therapeutic agents activating PGC-1 would be valuable for treating neurodegenerative diseases in which mitochondrial dysfunction and oxidative damage play an important pathogenic role.

Mutant A53T alpha-synuclein induces neuronal death by increasing mitochondrial autophagy.

Parkinson disease is characterized by the accumulation of aggregated α-synuclein as the major component of the Lewy bodies. α-Synuclein accumulation in turn leads to compensatory effects that may include the up-regulation of autophagy. Another common feature of Parkinson disease (PD) is mitochondrial dysfunction. Here, we provide evidence that the overactivation of autophagy may be a link that connects the intracellular accumulation of α-synuclein with mitochondrial dysfunction. We found that the activation of macroautophagy in primary cortical neurons that overexpress mutant A53T α-synuclein leads to massive mitochondrial destruction and loss, which is associated with a bioenergetic deficit and neuronal degeneration. No mitochondrial removal or net loss was observed when we suppressed the targeting of mitochondria to autophagosomes by silencing Parkin, overexpressing wild-type Mitofusin 2 and dominant negative Dynamin-related protein 1 or blocking autophagy by silencing autophagy-related genes. The inhibition of targeting mitochondria to autophagosomes or autophagy was also partially protective against mutant A53T α-synuclein-induced neuronal cell death. These data suggest that overactivated mitochondrial removal could be one of the contributing factors that leads to the mitochondrial loss observed in PD models.

Loss of mitochondrial membrane potential is associated with increase in mitochondrial volume: Physiological role in neurones

Mitochondrial volume homeostasis is a housekeeping cellular function, thought to help regulate oxidative capacity, apoptosis, and mechanical signaling. The volume is mainly regulated by potassium flux into and out of the matrix and controlled by the electrochemical potential. Mitochondrial depolarization will therefore affect this flux but studies showing how have not been consistent, and it is unclear what mitochondrial volume changes also occur. The aim of the present study was to investigate mitochondrial volume changes in permeabilized neurons under various bioenergetic conditions using deconvolution confocal microscopy. Under control conditions, mitochondria in situ appeared rod‐shaped with mean length, surface area, and volume values of 2.29 ± 0.10 µm, 1.41 ± 0.10 µm2, and 0.062 ± 0.006 µm3, respectively (n = 42). Valinomycin, a K+‐selective ionophore, increased mitochondrial volume by 63 ± 22%, although surface area was almost unchanged because mitochondrial shape became more spherical. Pinacidil, an opener of mitochondrial ATP‐dependent channels, produced similar effects, although some mitochondria were insensitive to its action. Mitochondrial depolarization with the protonophore FCCP, or with respiratory chain inhibitors antimycin and sodium azide was associated with a considerable increase in mitochondrial volume (by 75%–140%). Effects of mitochondrial modulators were also studied in intact neurones. Tracking of single mitochondria showed that during 65 ± 2% of their time, mitochondria were motile with an average velocity of 0.19 ± 0.01 µm/s. Antimycin, azide, and FCCP induced mitochondrial swelling and significantly decreased mitochondrial motility. In the presence of pinacidil, swollen mitochondria had reduced their motility, although mitochondria with normal volume stayed motile. These data show that mitochondrial depolarization was followed by significant swelling, which, in turn, impaired mitochondrial trafficking. J. Cell. Physiol. 206: 347–353, 2006.

Principles of the mitochondrial fusion and fission cycle in neurons

Summary Mitochondrial fusion–fission dynamics play a crucial role in many important cell processes. These dynamics control mitochondrial morphology, which in turn influences several important mitochondrial properties including mitochondrial bioenergetics and quality control, and they appear to be affected in several neurodegenerative diseases. However, an integrated and quantitative understanding of how fusion–fission dynamics control mitochondrial morphology has not yet been described. Here, we took advantage of modern visualisation techniques to provide a clear explanation of how fusion and fission correlate with mitochondrial length and motility in neurons. Our main findings demonstrate that: (1) the probability of a single mitochondrion splitting is determined by its length; (2) the probability of a single mitochondrion fusing is determined primarily by its motility; (3) the fusion and fission cycle is driven by changes in mitochondrial length and deviations from this cycle serves as a corrective mechanism to avoid extreme mitochondrial length; (4) impaired mitochondrial motility in neurons overexpressing 120Q Htt or Tau suppresses mitochondrial fusion and leads to mitochondrial shortening whereas stimulation of mitochondrial motility by overexpressing Miro-1 restores mitochondrial fusion rates and sizes. Taken together, our results provide a novel insight into the complex crosstalk between different processes involved in mitochondrial dynamics. This knowledge will increase understanding of the dynamic mitochondrial functions in cells and in particular, the pathogenesis of mitochondrial-related neurodegenerative diseases.

Dehydroepiandrosterone sulphate prevents oxygen–glucose deprivation-induced injury in cerebellar granule cell culture

Decreased levels of dehydroepiandrosterone sulphate have been hypothesized to contribute to increased vulnerability of the ageing or stressed human brain to ischemia. To help to address the question of whether of dehydroepiandrosterone sulphate has a possible neuroprotective effect against ischemic neuronal injury, we tested its effect on the neurodegeneration induced by oxygen-glucose deprivation in rat cultured cerebellar granule cells. Dehydroepiandrosterone sulphate added to the medium after injury demonstrated a neuroprotective effect with a median inhibitory concentration of 0.5 microM. At 10 microM concentration almost full neuroprotection was observed. Even more pronounced neuroprotective effect was found when dehydroepiandrosterone sulphate was added for 48h before injury. Furthermore, partial neuroprotection of dehydroepiandrosterone sulphate was also found against 1-methyl-4-phenylpyridinium, colchicine, glutamate and N-methyl-D-aspartate-induced toxicity. Further analysis demonstrated that dehydroepiandrosterone sulphate eliminated the apoptotic features of the oxygen-glucose deprivation-induced neuronal death: DNA fragmentation and nuclear condensation/fragmentation.Thus, our data suggest that dehydroepiandrosterone sulphate may have therapeutic potential in the prevention and treatment of ischemic/hypoxic neuronal damage. The neuroprotective action of dehydroepiandrosterone sulphate was inhibited by both a GABA(A) receptor-linked chloride channel agonist and an antagonist, pentobarbital and picrotoxin, respectively. It seems that GABA(A) receptor-mediated neuronal inhibition as well as neuronal excitation can reduce the neuroprotective action of dehydroepiandrosterone sulphate.

Sarcoplasmic reticulum function in determining atrioventricular contractile differences in rat heart

The relationships between the contractile characteristics and the sarcoplasmic reticulum (SR) function of rat atrial and ventricular trabeculae were compared. The isometric developed tension (DT) and the rates of contraction (+dT/d t) and relaxation (-dT/d t) normalized to cross-sectional area were 3.7, 2.2, and 1.8 times lower, respectively, in intact atrial strips compared with ventricular strips, whereas +dT/d t and -dT/d t(normalized to DT) were 2.3 and 2.8 times higher, respectively, in atria. Atria exhibited a maximal potentiation of DT after shorter rest periods than ventricles and a lower reversal for prolonged rest periods. Caffeine-induced tension transients in saponin-permeabilized fibers suggested that the Ca2+concentration released in atrial myofibrils reached a lower maximum and decayed more slowly than in ventricular preparations. However, the tension-time integrals indicated an equivalent capacity of sequestrable Ca2+ in SR from both tissues. In atrial, as in ventricular myocardium, the SR Ca2+ uptake was more efficiently supported by ATP produced by the SR-bound MM form of creatine kinase (CK; MM-CK) than by externally added ATP, suggesting a tight functional coupling between the SR Ca2+adenosinetriphosphatase (ATPase) and MM-CK. The maximal rate of oxalate-supported Ca2+ uptake was two times higher in atrial than in ventricular tissue homogenates. The SR Ca2+-ATPase 2a mRNA content normalized to 18S RNA was 38% higher in atria than in ventricles, whereas the amount of mRNA encoding the α-myosin heavy chain, calsequestrin, and the ryanodine receptor was similar in both tissues. Thus a lower amount of readily releasable Ca2+ together with a faster uptake rate may partly account for the shorter time course and lower tension development in intact atrial myocardium compared with ventricular myocardium.The relationships between the contractile characteristics and the sarcoplasmic reticulum (SR) function of rat atrial and ventricular trabeculae were compared. The isometric developed tension (DT) and the rates of contraction (+ dT/dt) and relaxation (-dT/dt) normalized to cross-sectional area were 3.7, 2.2, and 1.8 times lower, respectively, in intact atrial strips compared with ventricular strips, whereas + dT/dt and -dT/dt (normalized to DT) were 2.3 and 2.8 times higher, respectively, in atria. Atria exhibited a maximal potentiation of DT after shorter rest periods than ventricles and a lower reversal for prolonged rest periods. Caffeine-induced tension transients in saponin-permeabilized fibers suggested that the Ca2+ concentration released in atrial myofibrils reached a lower maximum and decayed more slowly than in ventricular preparations. However, the tension-time integrals indicated an equivalent capacity of sequestrable Ca2+ in SR from both tissues. In atrial, as in ventricular myocardium, the SR Ca2+ uptake was more efficiently supported by ATP produced by the SR-bound MM form of creatine kinase (CK; MM-CK) than by externally added ATP, suggesting a tight functional coupling between the SR Ca2+ adenosinetriphosphatase (ATPase) and MM-CK. The maximal rate of oxalate-supported Ca2+ uptake was two times higher in atrial than in ventricular tissue homogenates. The SR Ca(2+)-ATPase 2a mRNA content normalized to 18S RNA was 38% higher in atria than in ventricles, whereas the amount of mRNA encoding the alpha-myosin heavy chain, calsequestrin, and the ryanodine receptor was similar in both tissues. Thus a lower amount of readily releasable Ca2+ together with a faster uptake rate may partly account for the shorter time course and lower tension development in intact atrial myocardium compared with ventricular myocardium.

Mitochondrial Swelling Impairs the Transport of Organelles in Cerebellar Granule Neurons

Organelle transport in neuronal processes is central to the organization, developmental fate, and functions of neurons. Organelles must be transported through the slender, highly branched neuronal processes, making the axonal transport vulnerable to any perturbation. However, some intracellular structures like mitochondria are able to considerably modify their volume. We therefore hypothesized that swollen mitochondria could impair the traffic of other organelles in neurite shafts. To test this hypothesis, we have investigated the effects of mitochondrial swellers on the organelle traffic. Our data demonstrate that treatment of neurons with potassium ionophore valinomycin led to the fast time-dependent inhibition of organelle movement in cerebellar granule neurons. Similar inhibition was observed in neurons treated with the inhibitors of the mitochondrial respiratory chain, sodium azide and antimycin, which also induced swelling. No decrease in the motility of organelles was observed in cultures treated with inhibitors of ATP production or transport, oligomycin or bongkrekic acid, suggesting that inhibition of the ATP-generating activity itself without swelling does not affect the motility of organelles. The effect of swellers on the traffic was more important in thin processes, thus indicating the role of steric hindrance of swollen mitochondria. We propose that the size and morphology of the transported cargo is also relevant for seamless axonal transport and speculate that mitochondrial swelling could be one of the reasons for impaired organelle transport in neuronal processes.

Up-regulation of lysosomal cathepsin L and autophagy during neuronal death induced by reduced serum and potassium

Serum and potassium deprivation‐induced neuronal death on the primary culture of rat cerebellar granule neurons is being widely used as an in vitro model of neurodegeneration and neuronal apoptosis. In our experiments, serum and potassium deprivation for 12 h induced neuronal death in ≈ 20% of cerebellar granule neurons as demonstrated by Trypan Blue assay. Neuronal death was accompanied by a transient increase in the intralysosomal cathepsin L activity, which preceded neuronal death. During this time, the lysosomal membrane integrity remained preserved and no leakage of cathepsin L into the cytosol was seen. Ultrastructural analysis revealed the appearance of multiple vacuoles and autophagosomes in the cytoplasmatic compartment of serum‐ and potassium‐deprived granule neurons. Addition of selective cathepsin L inhibitors or of the autophagy inhibitor 3‐methyladenine provided partial protection against serum and potassium deprivation‐induced death. Our data also show that combining cathepsin L inhibitors and caspase‐3 inhibitors leads to a synergistic neuroprotective effect against serum and potassium deprivation. The results of the current study suggest that activation of the autophagosomal–lysosomal compartment plays an important role in neuronal death induced by serum and potassium deprivation in cultured cerebellar granule cells.

Structural and functional adaptations of striated muscles to CK deficiency.

In adult mammalian muscle cells, energy consuming processes are mainly localized to the sarcolemma, sarcoplasmic reticulum (SR) and myofibrillar compartments, while energy production occurs within mitochondria or glycolytic complexes. Due to the restricted diffusion of adenine nucleotides near the active sites of ATPases involved in contractile activity and calcium homeostasis, there are multiple local systems that can locally rephosphorylate ADP and provide ATP. The creatine kinase (CK) system, with specific isoenzymes localized within each compartment, efficiently controls local adenylate pools and links energy production and utilization. However, mice lacking one or both of the MM-CK and mi-CK isoforms (CK−/−) are viable and develop almost normal cardiac and skeletal muscle function under the conditions of moderate workload, suggesting adaptations or other mechanisms that may ensure efficient energy transfer. While fixed CK is essentially important, other systems could also be involved as well, such as bound glycolytic enzymes or adenylate kinase. We have shown that, additionally, a direct functional interplay exists between mitochondria and sarcoplasmic reticulum, or between mitochondria and myofilaments in muscle cells, that catalyzes direct energy and signal transfer between organelles. In cardiac cells of CK−/− mice, marked cytoarchitectural modifications were observed, and direct adenine nucleotide channeling between mitochondria and organelles was very effective to rescue SR and myofilament functions. In fast skeletal muscles, increased oxidative capacity also indicates compensatory mechanisms. In mutant mice, mitochondrial capacity increases and a direct energy channeling occurs between mitochondria on one hand and ATP consuming sites on the other. However, these systems appear to be insufficient to fully compensate for the lack of CK at high workload.It can be concluded that local rephosphorylation of ADP is a crucial regulatory point in highly differentiated and organized muscle cells to ensure contractile diversity and efficiency and that the CK system is important to control energy fluxes and energy homeostasis.

BECN1 is involved in the initiation of mitophagy: It facilitates PARK2 translocation to mitochondria

The autophagy protein BECN1/Beclin 1 is known to play a central role in autophagosome formation and maturation. The results presented here demonstrate that BECN1 interacts with the Parkinson disease-related protein PARK2. This interaction does not require PARK2 translocation to mitochondria and occurs mostly in cytosol. However, our results suggest that BECN1 is involved in PARK2 translocation to mitochondria because loss of BECN1 inhibits CCCP- or PINK1 overexpression-induced PARK2 translocation. Our results also demonstrate that the observed PARK2-BECN1 interaction is functionally important. Measurements of the level of MFN2 (mitofusin 2), a PARK2 substrate, demonstrate that depletion of BECN1 prevents PARK2 translocation-induced MFN2 ubiquitination and loss. BECN1 depletion also rescues the MFN2 loss-induced suppression of mitochondrial fusion. In sum, our results demonstrate that BECN1 interacts with PARK2 and regulates PARK2 translocation to mitochondria as well as PARK2-induced mitophagy prior to autophagosome formation.