Cerebral energy state, mitochondrial function, and redox state measurements in transient ischemia.

Earlier results are reviewed suggesting that transient pronounced, incomplete cerebral ischemia could be more deleterious for the recovery of brain tissue energy state than a complete interruption of the blood flow. Measurements of respiratory function of brain mitochondria, isolated after 30 min of either complete or incomplete ischemia, demonstrated a similar inhibition of respiratory activity and maximal phosphorylation rates in both situations. This inhibition was totally normalized during recirculation after complete ischemia while a further deterioration was found after incomplete ischemia. The in vivo alterations of the cortical tissue distribution of redox states during transient, incomplete ischemia (15--60 min) were measured using a flying spot fluorometer, which gives a real-time and on-line display of the tissue distribution of NADH and oxidized flavoprotein. A reoxidation in both systems was demonstrated during the recirculation period and the distribution of redox states showed no further heterogeneity in the postischemic period as compared to the preischemic distribution. It is concluded that reoxygenation of the brain tissue is possible even after long periods of incomplete ischemia. The normal distribution of redox states during recirculation suggests that mechanisms other than an impaired or inhomogeneous oxygen delivery during the postischemic period are responsible for the failure in recovery of mitochondrial function and tissue energy state.     

THE CONTROL OF PYRUVATE DEHYDROGENASE IN ISOLATED BRAIN MITOCHONDRIA

Abstract— The activity and control of the pyruvate dehydrogenase complex in isolated rat brain mitochondria has been studied. The activity of this complex in mitochondria as isolated from normal fed rats was 78 ± 10nmol.min⁻¹ mg mitochondrial protein⁻¹ (n = 18) which represented 70% of the total pyruvate dehydrogenase activity. The pyruvate dehydrogenase in isolated brain mitochondria could be inactivated by incubation in the presence of ATP, oligomycin and NaF. The rate of inactivation was dependent upon the added ATP concentration but inactivation below approx 30% of the total pyruvate dehydrogenase activity could not be achieved. The inactivation of pyruvate dehydrogenase in brain mitochondria was inhibited by pre-incubation with pyruvate. Reactivation of inactivated pyruvate dehydrogenase in rat brain mitochondria was incomplete in the incubation medium unless 10mM-Mg²⁺+ 1 mM-Ca²⁺ were added; NaF, however, prevented any reactivation (Fig. 4). It is concluded that the pyruvate dehydrogenase complex in rat brain mitochondria is controlled in a manner similar to that in other tissues, and that pyruvate protection of pyruvate dehydrogenase activity may be important in maintaining brain energy metabolism.     

Import of an incompletely folded precursor protein into isolated mitochondria requires an energized inner membrane, but no added ATP.

We have studied the post-translational import of incomplete precursor chains into isolated yeast mitochondria. The precursor was a fusion protein containing a mitochondrial presequence attached to mouse dihydrofolate reductase. In vitro-synthesis of the precursor was interrupted by the elongation inhibitor cycloheximide and the arrested nascent chains cosedimenting with ribosomes were released by EDTA. These incomplete chains were efficiently imported by isolated yeast mitochondria; their import resembled that of the complete precursor in requiring an energized inner membrane and a mitochondrial presequence. It differed from that of the completed precursor in its resistance to methotrexate (which only binds to correctly folded dihydrofolate reductase) and its independence of added ATP. The incomplete chains were also more sensitive to proteinase K than the completed precursor. We conclude that the incomplete chains were incompletely folded and suggest that the lack of tight folding caused import into mitochondria to become independent of added ATP. This implies that ATP may participate, directly or indirectly, in the unfolding of the precursor for its transport into mitochondria.     

Toxic action of 2'-chloro-2,4-dinitro-5',6-di(trifluoromethyl) diphenylamine in the rat.

2'-Chloro-2,4-dinitro-5',6-di(trifluoromethyl)diphenylamine (CDTD) is a potent uncoupler of oxidative phosphorylation in isolated rat liver or brain mitochondria. The concentration of CDTD causing 50% uncoupling in vitro is dependent on the mitochdonrial protein concentration and is 2 nM at 0.9 mg protein/ml for rat liver mitochondria. Oxidative phosphorylation can be restored to CDTD uncoupled liver mitochondria by the addition of a 10 000-fold molar excess of bovine serum albumin to DCTD. Rats given a lethal dose (7.0 mumol/kg) of CDTD intrapertioneally show signs of toxicity typical of uncoupling agents. Mitochondria isolated from the livers of these rats show almost complete inhibition of ATP synthesis and mitochondria obtained from the livers of rats at various times after a single oral dose show maximal inhibition of ATP synthesis 4 h after dosing with complete recovery by about 24 h. A single oral administration of 58 mumol/kg or above, but not intraperitoneal injection, of CDTD into rats produced an increase in the water content of the brain and spinal cord. The additional fluid has been shown to contain Na+ ions. The increase in cerebral fluid is dose related, no effect being seen at 23 mumol/kg. This extra fluid is thought to be responsible for the hind limb weakness observed in these rats. These observations suggest that there are two facets to CDTD toxicity: early deaths (within 2 h), which appear to be due to uncoupling of oxidative phosphorylation, and delayed deaths, 2--3 days after dosing which are probably related to an increase in fluid in the brain and spinal cord.     

Silver carbonate staining reveals mitochondrial heterogeneity.

Silver staining methods, when selective, yield a high-contrast and high-resolution image in optical microscopy. A classical method for silver impregnation of mitochondria has been applied to murine tissues and reveals a marked heterogeneity among mitochondria in single cells. This heterogeneity can be detected in the optical microscope but is even more evident at the ultrastructural level. The differences in staining intensity may reflect different stages in the mitochondrial life cycle. The progressive accumulation of uranyl-argyrophilic material may be a marker of mitochondrial aging. This highly selective staining procedure may be of use in studies of mitochondrial changes under pathological conditions and during apoptosis.     

Rapid Isolation of Metabolically Active Mitochondria from Rat Brain and Subregions Using Percoll Density Gradient Centrifugation

Two procedures are described for isolating free (nonsynaptosomal) mitochondria from rat brain. Both procedures employ a discontinuous Percoll gradient and yield well coupled mitochondria which exhibit high rates of respiratory activity and contain little residual contamination by synaptosomes or myelin. The procedures are considerably more rapid than methods described previously for the isolation of brain mitochondria and do not require an ultracentrifuge or swing-out rotor. The first method separates mitochondria by gradient centrifugation from a P2 (crude mitochondrial) fraction and is likely to be widely applicable for studies in which at least 500 mg of tissue are available as starting material. In the second method, the unfractionated homogenate is subjected directly to gradient centrifugation. This method requires the preparation of more gradients (per gram of tissue) than the first method and yields a subcellular fraction with slightly more synaptosomal contamination. However, this second procedure is more rapid, requires less manipulation of the tissue, and is suitable for obtaining mitochondria with well preserved metabolic characteristics from subregions of single rat brains.     

Calcium transport and proton electrochemical potential gradient in mitochondria from guinea-pig cerebral cortex and rat heart

A method is described for the preparation of ;free' and ;synaptosomal' brain mitochondria from fractions of guinea-pig cerebral cortex respectively depleted and enriched in synaptosomes. Both preparations of mitochondria have a low membrane H(+) conductance, a high capacity to phosphorylate ADP, and a capacity to accumulate Ca(2+) at rates limited by the activity of the respiratory chain. Ca(2+) transport by ;free' brain mitochondria is compared with that of heart mitochondria. The Ca(2+) conductance of ;free' brain mitochondria was at least 20 times that for rat heart mitochondria. Ca(2+) uptake by brain mitochondria increased the pH gradient and decreased membrane potential, whereas little change occurred during the much slower uptake by heart mitochondria. In the presence of ionophore A23187, dissipative Ca(2+) cycling decreased the H(+) electrochemical potential gradient of brain mitochondria from 190 to 60mV, but caused only a slight decrease with heart mitochondria, although the ionophore lowered the pH gradient and increased membrane potential. The Ca(2+) conductance of ;free' brain mitochondria is distinctive in showing a hyperbolic dependency on free Ca(2+) concentration. In the presence of Ruthenium Red, a rapid Na(+)-dependent Ca(2+) efflux occurs. The H(+) electrochemical potential gradient is maintained during this efflux, and membrane potential increases, with both ;free' brain and heart mitochondria. The Na(+) requirement for Ca(2+) efflux appears not to be related to the high Na(+)/H(+) exchange activity but may represent a direct exchange of Na(+) for Ca(2+).     

Preparation and properties of mitochondria derived from synaptosomes.

A method has been developed whereby a fraction of rat brain mitochondria (synaptic mitochondria) was isolated from synaptosomes. This brain mitochondrial fraction was compared with the fraction of "free" brain mitochondria (non-synaptic) isolated by the method of Clark & Nicklas (1970). (J. Biol. Chem. 245, 4724-4731). Both mitochondrial fractions are shown to be relatively pure, metabolically active and well coupled. 2. The oxidation of a number of substrates by synaptic and non-synaptic mitochondria was studied and compared. Of the substrates studied, pyruvate plus malate was oxidized most rapidly by both mitochondrial populations. However, the non-synaptic mitochondria oxidized glutamate plus malate almost twice as rapidly as the synaptic mitochondria. 3. The activities of certain tricarboxylic acid-cycle and related enzymes in synaptic and non-synaptic mitochondria were determined. Citrate synthase (EC 4.1.3.7), isocitrate dehydrogenase (EC 1.1.1.41) and malate dehydrogenase (EC 1.1.1.37) activities were similar in both fractions, but pyruvate dehydrogenase (EC 1.2.4.1) activity in non-synaptic mitochondria was higher than in synaptic mitochondria and glutamate dehydrogenase (EC 1.4.1.3) activity in non-synaptic mitochondria was lower than that in synaptic mitochondria. 4. Comparison of synaptic and non-synaptic mitochondria by rate-zonal separation confirmed the distinct identity of the two mitochondrial populations. The non-synaptic mitochondria had higher buoyant density and evidence was obtained to suggest that the synaptic mitochondria might be heterogeneous. 5. The results are also discussed in the light of the suggested connection between the heterogeneity of brain mitochondria and metabolic compartmentation.     

Perfusion Method for Preparing Pig Brain Cortex for Golgi-Cox Impregnation

The perfusion procedure described in this paper produces high quality impregnation of pig visual and somatosensory cortical neurons with a Golgi-Cox solution. Starting within 30 min after death, pig heads were perfused with a fixative solution composed of a mixture (v/v) of liquid phenol, 5%; formalin, 14%; ethylene glycol, 25%; methanol, 28%; and water, 28% for two periods of 4 hr each. After perfusion, the heads were chilled for at least 18 hr. The entire brain was removed from the skull and then placed in 10% buffered formalin, where it remained for at least 10 days before taking the blocks that were to be immersed in the Golgi-Cox solution. Three weeks spent in the Golgi-Cox solution typically produced uniform neuron impregnation. The tissue blocks were then embedded in celloidin and sectioned at 120 μm. This procedure avoids the following difficulties: Golgi-Cox methods that produced excellent results with rodent or primate tissue were unsuccessful with pig tissue, placing fresh tissue in Golgi-Cox solution resulted in incomplete neuron impregnation, and immersion fixation in 10% buffered formalin without perfusion resulted in excessive staining of glia.     

Perfusion method for preparing pig brain cortex for Golgi-Cox impregnation

The perfusion procedure described in this paper produces high quality impregnation of pig visual and somatosensory cortical neurons with a Golgi-Cox solution. Starting within 30 min after death, pig heads were perfused with a fixative solution composed of a mixture (v/v) of liquid phenol, 5%; formalin, 14%; ethylene glycol, 25%; methanol, 28%; and water, 28% for two periods of 4 hr each. After perfusion, the heads were chilled for at least 18 hr. The entire brain was removed from the skull and then placed in 10% buffered formalin, where it remained for at least 10 days before taking the blocks that were to be immersed in the Golgi-Cox solution. Three weeks spent in the Golgi-Cox solution typically produced uniform neuron impregnation. The tissue blocks were then embedded in celloidin and sectioned at 120 micron. This procedure avoids the following difficulties: Golgi-Cox methods that produced excellent results with rodent or primate tissue were unsuccessful with pig tissue, placing fresh tissue in Golgi-Cox solution resulted in incomplete neuron impregnation, and immersion fixation in 10% buffered formalin without perfusion resulted in excessive staining of glia.     

Problems and experience in the light optical and histological presentation of glia cells]

1. 8 histological techniques and 13 modifications derived from those were tested on usefulness for the demonstration of glial cells in the adult rat brain. From these methods the impregnation techniques of Golgi-Kopsch, Valenzuela y Chacón and Rio del Hortega were modified according to a scheme of variance to find out the optimal variants. 2. The impregnation quality depends on the animal species, the animal age, the health of brains, the brain area, the balanced proportion of the treatment stages and the biochemical state of the glial cells. 3. The silver impregnation techniques are not so specific that only one glial type is stained, but one type prevails. The silver carbonate procedure according to Hortega allows to impregnate oligodendrocytes, microglial cells and astrocytes in frozen as well as in paraffin sections. The method of Golgi-Kopsch is more suited for oligodendrocytes and microglial cells than for astrocytes. Following the procedure of Valenzuela y Chacón especially astrocytes, but also microglial cells allow impregnation in both frozen and paraffin sections. 4. The different demonstration qualities of the proved methods call for critical examination of absolute measurements of cell size, length of processes and ramification density. 5. The presence of cell groups of different disposition towards impregnation within a glial type speaks for a biochemical inhomogeneity of the glial types.     

A reliable method for demonstrating axonal degeneration shortly after axotomy

A method has been elaborated by which degenerating axons can be selectively impregnated with silver. Based on reconsideration of the physicochemical mechanisms of the degeneration methods it takes advantage of physical developers over the chemical ones. The staining procedure is applied to frozen sections of brains fixed with formol. It consists of 6 steps: (1) pretreatment with alkaline hydroxylamine, (2) washing in acetic acid, (3) impregnation in silver nitrate in the presence of ferric ions, (4) washing in citric acid, (5) physical development, and (6) washing in acetic acid. By electron microscopy silver precipitates by this method are almost entirely restricted to the cytoplasm of dense, degenerating axons, sparing mitochondria and myelin sheaths. No special expertise is required to achieve reproducible results. Large numbers of sections treated simultaneously, and large sections, can be stained uniformly. Light microscopic criteria are described which help diagnose the source of possible failures. Low background staining allows dark field illumination and television image analysis to be applied. The method works at survival times of only 3 to 5 days after axotomy. Hence, degenerating axons and axon terminals can be stained in alternating sections from the same brain using this method and another being described separately, which, using different conditions, demonstrates degenerating axon terminals.     

Distinct characteristics of Ca(2+)-induced depolarization of isolated brain and liver mitochondria

Ca(2+)-induced mitochondrial depolarization was studied in single isolated rat brain and liver mitochondria. Digital imaging techniques and rhodamine 123 were used for mitochondrial membrane potential measurements. Low Ca(2+) concentrations (about 30--100 nM) initiated oscillations of the membrane potential followed by complete depolarization in brain mitochondria. In contrast, liver mitochondria were less sensitive to Ca(2+); 20 microm Ca(2+) was required to depolarize liver mitochondria. Ca(2+) did not initiate oscillatory depolarizations in liver mitochondria, where each individual mitochondrion depolarized abruptly and irreversibly. Adenine nucleotides dramatically reduced the oscillatory depolarization in brain mitochondria and delayed the onset of the depolarization in liver mitochondria. In both type of mitochondria, the stabilizing effect of adenine nucleotides completely abolished by an inhibition of adenine nucleotide translocator function with carboxyatractyloside, but was not sensitive to bongkrekic acid. Inhibitors of mitochondrial permeability transition cyclosporine A and bongkrekic acid also delayed Ca(2+)-depolarization. We hypothesize that the oscillatory depolarization in brain mitochondria is associated with the transient conformational change of the adenine nucleotide translocator from a specific transporter to a non-specific pore, whereas the non-oscillatory depolarization in liver mitochondria is caused by the irreversible opening of the pore.     

A Reliable Method for Demonstrating Axonal Degeneration Shortly After Axotomy

A method has been elaborated by which degenerating axons can be selectively impregnated with silver. Based on a reconsideration of the physicochemical mechanisms of the degeneration methods it takes advantage of physical developers over the chemical ones. The staining procedure is applied to frozen sections of brains fixed with formol. It consists of 6 steps: (1) pretreatment with alkaline hydroxylamine, (2) washing in acetic acid, (3) impregnation in silver nitrate in the presence of ferric ions, (4) washing in citric acid, (5) physical development, and (6) washing in acetic acid. By electron microscopy silver precipitates by this method are almost entirely restricted to the cytoplasm of dense, degenerating axons, sparing mitochondria and myelin sheaths. No special expertise is required to achieve reproducible results. Large numbers of sections treated simultaneously, and large sections, can be stained uniformly. Light microscopic criteria are described which help diagnose the source of possible failures. Low background staining allows dark field illumination and television image analysis to be applied. The method works at survival times of only 3 to 5 days after axotomy. Hence, degenerating axons and axon terminals can be stained in alternating sections from the same brain using this method and another being described separately, which, using different conditions, demonstrates degenerating axon terminals.     

Optical methods for probing mitochondrial function in brain slices.

Brain slice preparations have become useful tools for studying multiple facets of normal brain function and for investigations of brain pathophysiology. Recently, a variety of neurological disorders have been linked to dysfunction of brain mitochondria. In this report we discuss optical methods for probing mitochondrial function in brain slices. Absorption spectrophotometric and spectrofluorometric techniques are described for measuring changes in the redox activity of mitochondrial cytochromes and the primary respiratory chain substrate nicotinamide adenine dinucleotide (NADH), respectively. A spectrofluorometric method is described also for measuring changes in mitochondrial membrane potential using the potential-sensitive fluorescent indicator JC-1. These methods used together have proven to be useful for studying dysfunction of mitochondria following in vitro ischemia in hippocampal slices, and might also be valuable for investigations of mitochondrial involvement in other neurological disorders.     

SYNAPTIC AND NON-SYNAPTIC MITOCHONDRIA FROM RAT BRAIN: ISOLATION AND CHARACTERIZATION

Abstract— A method has been developed where by three distinct populations of metabolically active, well coupled and relatively pure mitochondria from rat brain may be prepared. Two mitochondrial populations are derived from synaptozomes and the third consists of 'free' (i.e. non-synaptic) mitochondria. These mitochondrial populations have been characterized with respect to both enzyme content and ability to oxidize substrates. The results indicate that these mitochondrial populations are heterogeneous with respect to maximal activities of certain enzymes concerned with the citric acid cycle and glutamate and 4-aminobutyrate metabolism as well as their ability to utilize various substrates. The data reported here also confirm that brain mitochondria are very heterogeneous and suggest that synaptic mitochondria may contain at least two sub-populations. The relations between the heterogeneity of brain mitochondria and the metabolic compartmentation of the citric acid cycle and related metabolites such as glutamate, aspartate and 4-aminobutyrate are briefly discussed in the light of two proposed models of metabolic compartmentation in the mammalian brain.     

Ultrastructure of the cerebral cortex and hippocampus of rats in the early postresuscitation period following total ischemia

The rat frontal brain cortex and CAr hippocampal region were studied on the 4th day after 10-min complete ischemia. It has been established that the number of "dark" osmiophilic neurons was increased. The reparative, destructive and adaptive processes in cells were observed. The most prominent destructive changes were found in CAr hippocampal region, they can be associated with the microcirculatory disturbances. The hypertrophic thread-like mitochondria appear in the nervous and glial cells, with the quantity of lipofuscin granules increasing. Lipofuscin and hypertrophic mitochondria are thought to provide energy exchange in the brain cells during the postischemic period, forming one of the mechanisms of intracellular adaptation to hypoxia.     

Distinct characteristics of Ca-induced depolarization of isolated brain and liver mitochondria

Ca²⁺-induced mitochondrial depolarization was studied in single isolated rat brain and liver mitochondria. Digital imaging techniques and rhodamine 123 were used for mitochondrial membrane potential measurements. Low Ca²⁺ concentrations (about 30-100 nM) initiated oscillations of the membrane potential followed by complete depolarization in brain mitochondria. In contrast, liver mitochondria were less sensitive to Ca²⁺; 20 μM Ca²⁺ was required to depolarize liver mitochondria. Ca²⁺ did not initiate oscillatory depolarizations in liver mitochondria, where each individual mitochondrion depolarized abruptly and irreversibly. Adenine nucleotides dramatically reduced the oscillatory depolarization in brain mitochondria and delayed the onset of the depolarization in liver mitochondria. In both type of mitochondria, the stabilizing effect of adenine nucleotides completely abolished by an inhibition of adenine nucleotide translocator function with carboxyatractyloside, but was not sensitive to bongkrekic acid. Inhibitors of mitochondrial permeability transition cyclosporine A and bongkrekic acid also delayed Ca²⁺-depolarization. We hypothesize that the oscillatory depolarization in brain mitochondria is associated with the transient conformational change of the adenine nucleotide translocator from a specific transporter to a non-specific pore, whereas the non-oscillatory depolarization in liver mitochondria is caused by the irreversible opening of the pore.     

Response of poly(adenylic acid) polymerase in rat liver nuclei and mitochondria to stravation and re-feeding with amino acids.

Poly(adenylic acid) polymerase was extracted from liver nuclei and mitochondria of rats either fed ad libitum, starved overnight or starved and then re-fed with a complete amino acid mixture for 1-3 h. The enzymes were partially purified and assayed by using exogenous primers. Starvation resulted in an 80% decrease in the total activity of the purified nuclear enzyme, and the mitochondrial enzyme activity diminished to almost zero after overnight starvation. Measurements of the protein content of whole nuclei or mitochondria and of the enzyme extracts from these organelles indicated that the decrease in enzyme activity on starvation was not caused by incomplete extraction of the enzyme from the starved animals. Re-feeding the animals with the complete amino acid mixture increased the total activity of poly(A) polymerase from the nuclei and mitochondria by 1.9-fold and 63-fold respectively. Under these conditions, the total protein content of the nuclei and mitochondria increased by only 13 and 32% respectively. These data indicate that poly(A) polymerase is one of the cellular proteins specifically regulated by amino acid supply.