A new method for quantifying mitochondrial axonal transport

Axonal transport of mitochondria is critical for neuronal survival and function. Automatically quantifying and analyzing mitochondrial movement in a large quantity remain challenging. Here, we report an efficient method for imaging and quantifying axonal mitochondrial transport using microfluidic-chamber-cultured neurons together with a newly developed analysis package named “MitoQuant”. This tool-kit consists of an automated program for tracking mitochondrial movement inside live neuronal axons and a transient-velocity analysis program for analyzing dynamic movement patterns of mitochondria. Using this method, we examined axonal mitochondrial movement both in cultured mammalian neurons and in motor neuron axons of Drosophila in vivo. In 3 different paradigms (temperature changes, drug treatment and genetic manipulation) that affect mitochondria, we have shown that this new method is highly efficient and sensitive for detecting changes in mitochondrial movement. The method significantly enhanced our ability to quantitatively analyze axonal mitochondrial movement and allowed us to detect dynamic changes in axonal mitochondrial transport that were not detected by traditional kymographic analyses.     

Mitochondrial transport in proline catabolism in plants: the existence of two separate translocators in mitochondria isolated from durum wheat seedlings

Abiotic stresses, such as high salinity or drought, can cause proline accumulation in plants. Such an accumulation involves proline transport into mitochondria where proline catabolism occurs. By using durum wheat seedlings as a plant model system, we investigated how proline enters isolated coupled mitochondria. The occurrence of two separate translocators for proline, namely a carrier solely for proline and a proline/glutamate antiporter, is shown in a functional study in which we found the following: (1) Mitochondria undergo passive swelling in isotonic proline solutions in a stereospecific manner. (2) Externally added l-proline (Pro) generates a mitochondrial membrane potential (ΔΨ) with a rate depending on the transport of Pro across the mitochondrial inner membrane. (3) The dependence of the rate of generation of ΔΨ on increasing Pro concentrations exhibits hyperbolic kinetics. Proline transport is inhibited in a competitive manner by the non-penetrant thiol reagent mersalyl, but it is insensitive to the penetrant thiol reagent N-ethylmaleimide (NEM). (4) No accumulation of proline occurs inside the mitochondria as a result of the addition of proline externally, whereas the content of glutamate increases both in mitochondria and in the extramitochondrial phase. (5) Glutamate efflux from mitochondria occurs at a rate which depends on the mitochondrial transport, and it is inhibited in a non-competitive manner by NEM. The dependence of the rate of glutamate efflux on increasing proline concentration shows saturation kinetics. The physiological role of carrier-mediated transport in the regulation of proline catabolism, as well as the possible occurrence of a proline/glutamate shuttle in durum wheat seedlings mitochondria, are discussed.Catello Di Martino, Roberto Pizzuto these authors contributed equally to the paper     

Kinesin-1 and Dynein are the primary motors for fast transport of mitochondria in Drosophila motor axons

To address questions about mechanisms of filament-based organelle transport, a system was developed to image and track mitochondria in an intact Drosophila nervous system. Mutant analyses suggest that the primary motors for mitochondrial movement in larval motor axons are kinesin-1 (anterograde) and cytoplasmic dynein (retrograde), and interestingly that kinesin-1 is critical for retrograde transport by dynein. During transport, there was little evidence that force production by the two opposing motors was competitive, suggesting a mechanism for alternate coordination. Tests of the possible coordination factor P150(Glued) suggested that it indeed influenced both motors on axonal mitochondria, but there was no evidence that its function was critical for the motor coordination mechanism. Observation of organelle-filled axonal swellings ("organelle jams" or "clogs") caused by kinesin and dynein mutations showed that mitochondria could move vigorously within and pass through them, indicating that they were not the simple steric transport blockades suggested previously. We speculate that axonal swellings may instead reflect sites of autophagocytosis of senescent mitochondria that are stranded in axons by retrograde transport failure; a protective process aimed at suppressing cell death signals and neurodegeneration.     

Factors influencing the activity of ornithine aminotransferase in isolated rat liver mitochondria.

1. The characteristics of ornithine catabolism by the aminotransferase pathway in isolated mitochondria were determined. 2. Ornithine synthesis from glutamate and glutamate gamma-semialdehyde produced by the oxidation of proline was studied. No ornithine was formed in the absence of rotenone. 3. The mechanism of ornithine transport was reinvestigated, and the existence of an ornithine+/H+ exchange system postulated. 4. The kinetics of ornithine transport, ornithine catabolism in intact mitochondria and ornithine aminotransferase activity in solubilized mitochondria were compared. It is concluded that ornithine aminotransferase activity in liver mitochondria is rate-limited by the transport of ornithine across the mitochondrial membrane, and that this enzyme is involved primarily in ornithine degradation rather than ornithine synthesis.     

Mitochondrial dysfunction in amyotrophic lateral sclerosis

The etiology of motor neuron degeneration in amyotrophic lateral sclerosis (ALS) remains to be better understood. Based on the studies from ALS patients and transgenic animal models, it is believed that ALS is likely to be a multifactorial and multisystem disease. Many mechanisms have been postulated to be involved in the pathology of ALS, such as oxidative stress, glutamate excitotoxicity, mitochondrial damage, defective axonal transport, glia cell pathology and aberrant RNA metabolism. Mitochondria, which play crucial roles in excitotoxicity, apoptosis and cell survival, have shown to be an early target in ALS pathogenesis and contribute to the disease progression. Morphological and functional defects in mitochondria were found in both human patients and ALS mice overexpressing mutant SOD1. Mutant SOD1 was found to be preferentially associated with mitochondria and subsequently impair mitochondrial function. Recent studies suggest that axonal transport of mitochondria along microtubules and mitochondrial dynamics may also be disrupted in ALS. These results also illustrate the critical importance of maintaining proper mitochondrial function in axons and neuromuscular junctions, supporting the emerging “dying-back” axonopathy model of ALS. In this review, we will discuss how mitochondrial dysfunction has been linked to the ALS variants of SOD1 and the mechanisms by which mitochondrial damage contributes to the disease etiology.     

Removing dysfunctional mitochondria from axons independent of mitophagy under pathophysiological conditions

Chronic mitochondrial dysfunction has been implicated in major neurodegenerative diseases. Long-term cumulative pathological stress leads to axonal accumulation of damaged mitochondria. Therefore, the early removal of defective mitochondria from axons constitutes a critical step of mitochondrial quality control. We recently investigated the axonal mitochondrial response to mild stress in wild-type neurons and chronic mitochondrial defects in amyotrophic lateral sclerosis (ALS)- and Alzheimer disease (AD)-linked neurons. We demonstrated that remobilizing stressed mitochondria is critical for maintaining axonal mitochondrial integrity. The selective release of the mitochondrial anchoring protein SNPH (syntaphilin) from stressed mitochondria enhances their retrograde transport toward the soma before PARK2/Parkin-mediated mitophagy is activated. This SNPH-mediated response is robustly activated during the early disease stages of ALS-linked motor neurons and AD-related cortical neurons. Our study thus reveals a new mechanism for the maintenance of axonal mitochondrial integrity through SNPH-mediated coordination of mitochondrial stress and motility that is independent of mitophagy.     

Glutamate transprot in rat kidney mitochondria

The quantitative characteristics of [U-14C]glutamate transport were determined in rotenone-inhibited energized rat kidney mitochondria at pH 7.0 and 28 degrees C. Glutamate efflux was observed to be first order with respect to matrix glutamate with a rate constant of 0.457 min-1. Uptake kinetic studies indicated that the Km of external glutamate was 1.4 mM and the Vmax 3.2 nmol/mg X min. These kinetic values were found to be unchanged at pH 6.6 or in mitochondria obtained from kidneys of chronically acidotic rats. Parallel studies of glutamate deamination were performed in which mitochondria were incubated in state 3, state 4, and with carbonyl cyanide p-trifluoromethoxyphenylhydrazone, in the presence of malonate. The oxidative deamination of glutamate determined with 1 and 10 mM glutamate never exceeded the simultaneously measured rate of glutamate transport. No glutamate was detectable within the mitochondrial matrix under the conditions of these metabolic experiments. The studies indicate that the glutamate hydroxyl transporter is quite slow and rate limiting for the oxidative deamination of external glutamate in rat kidney mitochondria.     

Quantitative characteristics of glutamate transport in rat liver mitochondria

1. The kinetics of glutamate transport into mitochondria were determined by using Bromocresol Purple to terminate the transport process. 2. Glutamate transport was found to have a V(max.) of 9.1nmol/min per mg of protein at pH6.9 and 20 degrees C; the K(m) for glutamate was 4mm. 3. The rate of glutamate deamination in intact mitochondria was tenfold slower than in disrupted mitochondria. 4. These results suggest that glutamate deamination may be controlled by the rate of glutamate transport. Possible consequences of these findings are discussed.     

Trafficking kinesin protein (TRAK)-mediated transport of mitochondria in axons of hippocampal neurons

In neurons, the proper distribution of mitochondria is essential because of a requirement for high energy and calcium buffering during synaptic neurotransmission. The efficient, regulated transport of mitochondria along axons to synapses is therefore crucial for maintaining function. The trafficking kinesin protein (TRAK)/Milton family of proteins comprises kinesin adaptors that have been implicated in the neuronal trafficking of mitochondria via their association with the mitochondrial protein Miro and kinesin motors. In this study, we used gene silencing by targeted shRNAi and dominant negative approaches in conjunction with live imaging to investigate the contribution of endogenous TRAKs, TRAK1 and TRAK2, to the transport of mitochondria in axons of hippocampal pyramidal neurons. We report that both strategies resulted in impairing mitochondrial mobility in axonal processes. Differences were apparent in terms of the contribution of TRAK1 and TRAK2 to this transport because knockdown of TRAK1 but not TRAK2 impaired mitochondrial mobility, yet both TRAK1 and TRAK2 were shown to rescue transport impaired by TRAK1 gene knock-out. Thus, we demonstrate for the first time the pivotal contribution of the endogenous TRAK family of kinesin adaptors to the regulation of mitochondrial mobility.     

Reversibility of energy-dependent Ca2+ accumulation in mitochondria

Ca2+ accumulation in energized rat liver mitochondria has been studied after the blockage of mitochondrial permeability transition pore (MPTP) by cyclosporin A. It is shown that Ca2+ transport is coupled to the countertransport of protons: from the matrix of mitochondria in the medium in the course of Ca2+ accumulation, and, on the contrary, from the medium to mitochondrial matrix after membrane depolarization. In standard incubation medium containing K+, Cl-, oxidation substrate (glutamate) and inorganic phosphate (H2PO4(-)) the observed stoichiometry of the exchange is 1Ca2+ : 1H+. In accordance with this exchange ratio, proton, as well as cation, transport follows the same first-order kinetics, which is characterized in both cases by very close values of reaction half-times and rate constants. It is shown that reversion of Ca2+ -uniporter, sensitive to ruthenium red, is necessary for Ca2+ - efflux from the matrix ofdeenergized mitochondria when MPTP is blocked by cyclosporin A. It is also shown that Ca2+ -uniporter reversion takes place only after membrane depolarization and permeabilization by protonophore CCCP. Calcium release from mitochondria in the presence of CCCP is accompanied by proton flow into the matrix. Both calcium and proton fluxes are sensitive to Ca2+ uniporter blocker, ruthenium red, which gives the evidence of the identity of Ca2+ -efflux and influx pathways. The data obtained lead to the conclusion that calcium-proton exchange is necessary for Ca2+ -uniporter reversion and the reversibility of energy-dependent Ca2+ -uptake in mitochondria.     

Effect of l-leucine on the nitrogen metabolism of isolated rat liver mitochondria

1. l-Leucine strongly activated intramitochondrial glutamate dehydrogenase in the direction of glutamate synthesis. 2. In the deamination direction, the enzyme was not stimulated by leucine. This was probably due to a rate-limiting transport of glutamate across the mitochondrial membrane. 3. The effect of leucine on the kinetic constants of glutamate dehydrogenase in a mitochondrial sonicate was studied. 4. In isolated mitochondria, leucine did not stimulate the synthesis of citrulline with glutamate as the source of NH(3). 5. Leucine very markedly stimulated the synthesis of glutamate from added 2-oxoglutarate+NH(4)Cl. 6. Under conditions where glutamate and citrulline could be synthesized simultaneously from added NH(4)Cl, leucine greatly increased glutamate synthesis at the expense of citrulline synthesis. 7. It is suggested that the intramitochondrial leucine concentration may be a factor influencing the nitrogen metabolism of the liver cell.     

Chronic elevation of extracellular glutamate due to transport blockade is innocuous for spinal motoneurons in vivo

Glutamate-mediated excitotoxicity has been considered to play an important role in the mechanism of spinal motoneuron death in amyotrophic lateral sclerosis (ALS), and some reports suggest that this excitotoxicity may be due to a decreased glutamate transport and the consequent elevation of its extracellular level. We have previously shown that short lasting increments in extracellular glutamate due to administration of the non-selective glutamate transport blocker l-2,4-trans-pyrrolidine-dicarboxylate (PDC) by microdialysis in the rat spinal cord do not induce motoneuron damage. In the present work we examined the potential involvement of chronic glutamate transport blockade as a causative factor of spinal motoneuron death and paralysis in vivo. Using osmotic minipumps, we infused directly in the spinal cord for up to 10 days PDC and another glutamate transport blocker, dl-threo-β-benzyloxyaspartate (TBOA), and we measured by means of microdialysis and HPLC the extracellular concentration of glutamate and other amino acids. We found that after the infusion of both PDC and TBOA the concentration of endogenous extracellular glutamate was 3–4-fold higher than that of the controls. Nevertheless, in spite of this elevation no motoneuron degeneration or gliosis were observed, assessed by histological examination and choline acetyltransferase and glial fibrillary acidic protein immunocytochemistry. In accord with this lack of toxic effect, no motor deficits, assessed by three motor activity tests, were observed.Because we had previously shown that under identical experimental conditions the infusion of α-amino-3-hydroxy-5-methyl-4-isoxazole propionate (AMPA) induced progressive motoneuron death and paralysis, we conclude that prolonged elevation of extracellular glutamate due to its transport blockade in vivo is innocuous for spinal motoneurons and therefore that these results do not support the hypothesis that glutamate transport deficiency plays a crucial role as a causal factor of spinal motoneuron degeneration in ALS.     

Unique anti-apoptotic activity of EAAC1 in injured motor neurons

Injured motor neurons of the adult rat can survive, whereas similar axotomy causes gradual motor neuron death in the adult mouse. We report that the decreased expression of the neuronal glutamate transporter excitatory amino-acid carrier 1 (EAAC1) following nerve injury is associated with motor neuron death in the mouse. Glutamate transporters play a crucial role in prevention of neuronal death by suppressing glutamate toxicity. However, the possible functional role of EAAC1 in preventing neuron death has not been resolved as compared with glial glutamate transporters such as GLT-1. Here, we have revealed a unique 'rescue' function of EAAC1, which is independent of removal of extracellular glutamate. During apoptotic stimuli, a mitochondrial protein, holocytochrome c synthetase (HCCS), translocates to outside the mitochondria, binds to and suppresses the X-linked inhibitor of apoptosis protein (XIAP), leading to activation of caspase-3. The N-terminus of EAAC1 can bind to HCCS, which interferes with the HCCS-XIAP association, and thereby maintain XIAP activity. This unique anti-apoptotic mechanism of EAAC1 functions in rescuing PC12 cells and motor neurons from NGF deprivation and nerve injury, respectively.     

Glutamate forward and reverse transport: from molecular mechanism to transporter-mediated release after ischemia

Glutamate transporters remove the excitatory neurotransmitter glutamate from the extracellular space after neurotransmission is complete, by taking glutamate up into neurons and glia cells. As thermodynamic machines, these transporters can also run in reverse, releasing glutamate into the extracellular space. Because glutamate is excitotoxic, this transporter-mediated release is detrimental to the health of neurons and axons, and it, thus, contributes to the brain damage that typically follows a stroke. This review highlights current ideas about the molecular mechanisms underlying glutamate uptake and glutamate reverse transport. It also discusses the implications of transporter-mediated glutamate release for cellular function under physiological and patho-physiological conditions.     

Transport of glutamate in rat-liver mitochondria

The transport of glutamate across the membrane of rat-liver mitochondria has been studied.

1. 1. Glutamate can be transported across the mitochondrial membrane in exchange for OH⁻ (or together with H⁺).

2. 2. Intramitochondrial glutamate is not extruded from the mitochondria by addition of aspartate when the mitochondria are preloaded with glutamate.

3. 3. N-Ethylmaleimide is a specific inhibitor of the movement of glutamate across the mitochondrial membrane.

Comparative studies on glutamate metabolism in synpatic and non-synaptic rat brain mitochondria.

1. The apparent Michaelis constants of the glutamate dehydrogenase (EC 1.4.1.3), the glutamate-oxaloacetate transaminase (EC 2.6.1.1) and the glutaminase (EC 3.5.1.2) of rat brain mitochondria derived from non-synaptic (M) and synaptic (SM2) sources were studied. 2. The kinetics of oxygen uptake of both populations of mitochondria in the presence of a fixed concentration of malate and various concentrations of glutamate or glutamine were investigated. 3. In both mitochondrial populations, glutamate-supported respiration in the presence of 2.5 mM-malate appears to be biphasic, one system (B) having an apparent Km for glutamate of 0.25 +/- 0.04 mM (n=7) and the other (A) of 1.64 +/- 0.5 mM (n=7) [when corrected for low-Km process, Km=2.4 +/- 0.75 mM (n=7)]. Aspartate production in these experiments followed kinetics of a single process with an apparent Km for glutamate of 1.8-2 mM, approximating to the high-Km process. 4. Oxygen-uptake measurement with both mitochondrial populations in the presence of malate and various glutamate concentrations in which amino-oxyacetate was present showed kinetics approximating only to the low-Km process (apparent Km for glutamate approximately 0.2 mM). Similar experiments in the presence of glutamate alone showed kinetics approximating only to the high-Km process (apparent Km for glutamate approximately 1-1.3 mM). 5. Oxygen uptake supported by glutamine (0-3 mM) and malate (2.5 mM) by the free (M) mitochondrial population, however, showed single-phase kinetics with an apparent Km for glutamine of 0.28 mM. 6. Aspartate and 2-oxoglutarate accumulation was measured in 'free' nonsynaptic (M) brain mitochondria oxidizing various concentrations of glutamate at a fixed malate concentration. Over a 30-fold increase in glutamate concentration, the flux through the glutamate-oxaloacetate transaminase increased 7--8-fold, whereas the flux through 2-oxoglutarate dehydrogenase increased about 2.5-fold. 7. The biphasic kinetics of glutamate-supported respiration by brain mitochondria in the presence of malate are interpreted as reflecting this change in the relative fluxes through transamination and 2-oxoglutarate metabolism.     

Mitochondrial biogenesis in the axons of vertebrate peripheral neurons

Mitochondria are widely distributed via regulated transport in neurons, but their sites of biogenesis remain uncertain. Most mitochondrial proteins are encoded in the nuclear genome, and evidence has suggested that mitochondrial DNA (mtDNA) replication occurs mainly or entirely in the cell body. However, it has also become clear that nuclear-encoded mitochondrial proteins can be translated in the axon and that components of the mitochondrial replication machinery reside there as well. We assessed directly whether mtDNA replication can occur in the axons of chick peripheral neurons labeled with 5-bromo-2'-deoxyuridine (BrdU). In axons that were physically separated from the cell body or had disrupted organelle transport between the cell bodies and axons, a significant fraction of mtDNA synthesis continued. We also detected the mitochondrial fission protein Drp1 in neurons by immunofluorescence or expression of GFP-Drp1. Its presence and distribution on the majority of axonal mitochondria indicated that a substantial number had undergone recent division in the axon. Because the morphology of mitochondria is maintained by the balance of fission and fusion events, we either inhibited Drp1 expression by RNAi or overexpressed the fusion protein Mfn1. Both methods resulted in significantly longer mitochondria in axons, including many at a great distance from the cell body. These data indicate that mitochondria can replicate their DNA, divide, and fuse locally within the axon; thus, the biogenesis of mitochondria is not limited to the cell body.     

Evidence indicating that pig renal phosphate-activated glutaminase has a functionally predominant external localization in the inner mitochondrial membrane

Phosphate-activated glutaminase in intact pig renal mitochondria was inhibited 50-70% by the sulfhydryl reagents mersalyl and N-ethylmaleimide (0.3-1.0 mM), when assayed at pH 7.4 in the presence of no or low phosphate (10 mM) and glutamine (2 mM). However, sulfhydryl reagents added to intact mitochondria did not inhibit the SH-enzyme beta-hydroxybutyrate dehydrogenase (a marker of the inner face of the inner mitochondrial membrane), but did so upon addition to sonicated mitochondria. This indicates that the sulfhydryl reagents are impermeable to the inner membrane and that regulatory sulfhydryl groups for glutaminase have an external localization here. The inhibition observed when sulfhydryl reagents were added to intact mitochondria could not be attributed to an effect on a phosphate carrier, but evidence was obtained that pig renal mitochondria have also a glutamine transporter, which is inhibited only by mersalyl and not by N-ethylmaleimide. Mersalyl and N-ethylmaleimide showed nondistinguishable effects on the kinetics of glutamine hydrolysis, affecting only the apparent Vmax for glutamine and not the apparent Km calculated from linear Hanes-Woolf plots. Furthermore, both calcium (which activates glutamine hydrolysis), as well as alanine (which has no effect on the hydrolytic rate), inhibited glutamine transport into the mitochondria, indicating that transport of glutamine is not rate-limiting for the glutaminase reaction. Desenzitation to inhibition by mersalyl and N-ethylmaleimide occurred when the assay was performed under optimal conditions for phosphate activated glutaminase (i.e. in the presence of 150 mM phosphate, 20 mM glutamine and at pH 8.6). Desenzitation also occurred when the enzyme was incubated with low concentrations of Triton X-100 which did not affect the rate of glutamine hydrolysis. Following incubation with [14C]glutamine and correction for glutamate in contaminating subcellular particles, the specific activity of [14C]glutamate in the mitochondria was much lower than that of the surrounding incubation medium. This indicates that glutamine-derived glutamate is released from the mitochondria without being mixed with the endogenous pool of glutamate. The results suggest that phosphate-activated glutaminase has a functionally predominant external localization in the inner mitochondrial membrane.     

Mitochondrial calcium flux in temperature-sensitive mutants of

The mechanisms of mitochondrial calcium flux in normal and temperature-sensitive mutants of were investigated. Adult mitochondria from all stocks, when analysed with an oxygen electrode, gave respiration rates which exhibited normal responses to adenosine diphosphate and uncoupling agents but no stimulation by calcium. In contrast, calcium stimulates the respiration rate of normal larval mitochondria particularly those of the second instar. This is not evident in second instar mitochondria from the temperature sensitive mutants. There is a rapid accumulation of mitochondrial calcium during normal larval ontogenesis. The levels in temperature-sensitive second instar mitochondria are higher than those of any of the normal larval stages. Adult mitochondria in all cases contain very low levels of calcium. The amount of calcium taken up by mitochondria of second instar temperature-sensitive mutants is lower than that of normal. This may reflect the higher endogenous levels already present in the former. The implications of these variations in calcium metabolism for the behavioural defects of the temperature sensitive mutants is discussed.     

MFN2 Couples Glutamate Excitotoxicity and Mitochondrial Dysfunction in Motor Neurons

Mitochondrial dysfunction plays a central role in glutamate-evoked neuronal excitotoxicity, and mitochondrial fission/fusion dynamics are essential for mitochondrial morphology and function. Here, we establish a novel mechanistic linker among glutamate excitotoxicity, mitochondrial dynamics, and mitochondrial dysfunction in spinal cord motor neurons. Ca²⁺-dependent activation of the cysteine protease calpain in response to glutamate results in the degradation of a key mitochondrial outer membrane fusion regulator, mitofusin 2 (MFN2), and leads to MFN2-mediated mitochondrial fragmentation preceding glutamate-induced neuronal death. MFN2 deficiency impairs mitochondrial function, induces motor neuronal death, and renders motor neurons vulnerable to glutamate excitotoxicity. Conversely, MFN2 overexpression blocks glutamate-induced mitochondrial fragmentation, mitochondrial dysfunction, and/or neuronal death in spinal cord motor neurons both in vitro and in mice. The inhibition of calpain activation also alleviates glutamate-induced excitotoxicity of mitochondria and neurons. Overall, these results suggest that glutamate excitotoxicity causes mitochondrial dysfunction by impairing mitochondrial dynamics via calpain-mediated MFN2 degradation in motor neurons and thus present a molecular mechanism coupling glutamate excitotoxicity and mitochondrial dysfunction.