Preferential loss of ATP-dependent long-chain fatty acid activating enzyme in mitochondria prepared using Nagarse

A practical perspective on how to develop, implement, execute, and reproduce high-resolution respirometry experiments: The physiologist's guide to an Oroboros O2k

The development of high-resolution respirometry (HRR) has greatly expanded the analytical scope to study mitochondrial respiratory control relative to specific tissue/cell types across various metabolic states. Specifically, the Oroboros Oxygraph 2000 (O2k) is a common tool for measuring rates of mitochondrial respiration and is the focus of this perspective. The O2k platform is amenable for answering numerous bioenergetic questions. However, inherent variability with HRR-derived data, both within and amongst users, can impede progress in bioenergetics research. Therefore, we advocate for several vital considerations when planning and conducting O2k experiments to ultimately enhance transparency and reproducibility across laboratories. In this perspective, we offer guidance for best practices of mitochondrial preparation, protocol selection, and measures to increase reproducibility. The goal of this perspective is to propagate the use of the O2k, enhance reliability and validity for both new and experienced O2k users, and provide a reference for peer reviewers.

The blood lactate/pyruvate equilibrium affair

The Lactate Shuttle hypothesis is supported by a variety of techniques including mass spectrometry analytics following infusion of carbon-labeled isotopic tracers. However, there has been controversy over whether lactate tracers measure lactate (L) or pyruvate (P) turnover. Here, we review the analytical errors, use of inappropriate tissue and animal models, failure to consider L and P pool sizes in modeling results, inappropriate tracer and blood sampling sites, and failure to anticipate roles of heart and lung parenchyma on L⇔P interactions. With support from magnetic resonance spectroscopy (MRS) and immunocytochemistry, we conclude that carbon-labeled lactate tracers can be used to quantitate lactate fluxes.

The tortuous path of lactate shuttle discovery: From cinders and boards to the lab and ICU

Once thought to be a waste product of oxygen limited (anaerobic) metabolism, lactate is now known to form continuously under fully oxygenated (aerobic) conditions. Lactate shuttling between producer (driver) and consumer cells fulfills at least 3 purposes; lactate is: (1) a major energy source, (2) the major gluconeogenic precursor, and (3) a signaling molecule. The Lactate Shuttle theory is applicable to diverse fields such as sports nutrition and hydration, resuscitation from acidosis and Dengue, treatment of traumatic brain injury, maintenance of glycemia, reduction of inflammation, cardiac support in heart failure and following a myocardial infarction, and to improve cognition. Yet, dysregulated lactate shuttling disrupts metabolic flexibility, and worse, supports oncogenesis. Lactate production in cancer (the Warburg effect) is involved in all main sequela for carcinogenesis: angiogenesis, immune escape, cell migration, metastasis, and self-sufficient metabolism. The history of the tortuous path of discovery in lactate metabolism and shuttling was discussed in the 2019 American College of Sports Medicine Joseph B. Wolffe Lecture in Orlando, FL.

Lactate as a fulcrum of metabolism

Mistakenly thought to be the consequence of oxygen lack in contracting skeletal muscle we now know that the L-enantiomer of the lactate anion is formed under fully aerobic conditions and is utilized continuously in diverse cells, tissues, organs and at the whole-body level. By shuttling between producer (driver) and consumer (recipient) cells lactate fulfills at least three purposes: 1] a major energy source for mitochondrial respiration; 2] the major gluconeogenic precursor; and 3] a signaling molecule. Working by mass action, cell redox regulation, allosteric binding, and reprogramming of chromatin by lactylation of lysine residues on histones, lactate has major influences in energy substrate partitioning. The physiological range of tissue [lactate] is 0.5–20 mM and the cellular Lactate/Pyruvate ratio (L/P) can range from 10 to >500; these changes during exercise and other stress-strain responses dwarf other metabolic signals in magnitude and span. Hence, lactate dynamics have rapid and major short- and long-term effects on cell redox and other control systems. By inhibiting lipolysis in adipose via HCAR-1, and muscle mitochondrial fatty acid uptake via malonyl-CoA and CPT1, lactate controls energy substrate partitioning. Repeated lactate exposure from regular exercise results in major effects on the expression of regulatory enzymes of glycolysis and mitochondrial respiration. Lactate is the fulcrum of metabolic regulation in vivo.

Kummitha C, Rosca MG, Fujioka H, Tandler B, Hoppel CL. Isolation of mitochondrial subpopulations from skeletal muscle: Optimizing recovery and preserving integrity

AIM

The subsarcolemmal (SSM) and interfibrillar (IFM) mitochondria in skeletal muscle appear to have distinct biochemical properties affecting metabolism in health and disease. The isolation of mitochondrial subpopulations has been a long-time challenge while the presence of a continuous mitochondrial reticulum challenges the view of distinctive SSM and IFM bioenergetics. Here, a comprehensive approach is developed to identify the best conditions to separate mitochondrial fractions.

METHODS

The main modifications to the protocol to isolate SSM and IFM from rat skeletal muscle were: (a) decreased dispase content and homogenization speed; (b) trypsin treatment of SSM fractions; (c) recentrifugation of mitochondrial fractions at low speed to remove subcellular components. To identify the conditions preserving mitochondrial function, integrity, and maximizing their recovery, microscopy (light and electron) were used to monitor effectiveness and efficiency in separating mitochondrial subpopulations while respiratory and enzyme activities were employed to evaluate function, recovery, and integrity.

RESULTS

With the modifications described, the total mitochondrial yield increased with a recovery of 80% of mitochondria contained in the original skeletal muscle sample. The difference between SSM and IFM oxidative capacity (10%) with complex-I substrate was significant only with a saturated ADP concentration. The inner and outer membrane damage for both subpopulations was <1% and 8%, respectively, while the respiratory control ratio was 16.

CONCLUSION

Using a multidisciplinary approach, conditions were identified to maximize SSM and IFM recovery while preserving mitochondrial integrity, biochemistry, and morphology. High quality and recovery of mitochondrial subpopulations allow to study the relationship between these organelles and disease.

The Science and Translation of Lactate Shuttle Theory

Once thought to be a waste product of anaerobic metabolism, lactate is now known to form continuously under aerobic conditions. Shuttling between producer and consumer cells fulfills at least three purposes for lactate: (1) a major energy source, (2) the major gluconeogenic precursor, and (3) a signaling molecule. "Lactate shuttle" (LS) concepts describe the roles of lactate in delivery of oxidative and gluconeogenic substrates as well as in cell signaling. In medicine, it has long been recognized that the elevation of blood lactate correlates with illness or injury severity. However, with lactate shuttle theory in mind, some clinicians are now appreciating lactatemia as a "strain" and not a "stress" biomarker. In fact, clinical studies are utilizing lactate to treat pro-inflammatory conditions and to deliver optimal fuel for working muscles in sports medicine. The above, as well as historic and recent studies of lactate metabolism and shuttling, are discussed in the following review.

Physiological and structural differences in spatially distinct subpopulations of cardiac mitochondria: influence of cardiac pathologies

Cardiac tissue contains discrete pools of mitochondria that are characterized by their subcellular spatial arrangement. Subsarcolemmal mitochondria (SSM) exist below the cell membrane, interfibrillar mitochondria (IFM) reside in rows between the myofibrils, and perinuclear mitochondria are situated at the nuclear poles. Microstructural imaging of heart tissue coupled with the development of differential isolation techniques designed to sequentially separate spatially distinct mitochondrial subpopulations have revealed differences in morphological features including shape, absolute size, and internal cristae arrangement. These findings have been complemented by functional studies indicating differences in biochemical parameters and, potentially, functional roles for the ATP generated, based upon subcellular location. Consequently, mitochondrial subpopulations appear to be influenced differently during cardiac pathologies including ischemia/reperfusion, heart failure, aging, exercise, and diabetes mellitus. These influences may be the result of specific structural and functional disparities between mitochondrial subpopulations such that the stress elicited by a given cardiac insult differentially impacts subcellular locales and the mitochondria contained within. The goal of this review is to highlight some of the inherent structural and functional differences that exist between spatially distinct cardiac mitochondrial subpopulations as well as provide an overview of the differential impact of various cardiac pathologies on spatially distinct mitochondrial subpopulations. As an outcome, we will instill a basis for incorporating subcellular spatial location when evaluating the impact of cardiac pathologies on the mitochondrion. Incorporation of subcellular spatial location may offer the greatest potential for delineating the influence of cardiac pathology on this critical organelle.

Lactate oxidation in human skeletal muscle mitochondria

Lactate is an important intermediate metabolite in human bioenergetics and is oxidized in many different tissues including the heart, brain, kidney, adipose tissue, liver, and skeletal muscle. The mechanism(s) explaining the metabolism of lactate in these tissues, however, remains unclear. Here, we analyze the ability of skeletal muscle to respire lactate by using an in situ mitochondrial preparation that leaves the native tubular reticulum and subcellular interactions of the organelle unaltered. Skeletal muscle biopsies were obtained from vastus lateralis muscle in 16 human subjects. Samples were chemically permeabilized with saponin, which selectively perforates the sarcolemma and facilitates the loss of cytosolic content without altering mitochondrial membranes, structure, and subcellular interactions. High-resolution respirometry was performed on permeabilized muscle biopsy preparations. By use of four separate and specific substrate titration protocols, the respirometric analysis revealed that mitochondria were capable of oxidizing lactate in the absence of exogenous LDH. The titration of lactate and NAD(+) into the respiration medium stimulated respiration (P ≤ 0.003). The addition of exogenous LDH failed to increase lactate-stimulated respiration (P = 1.0). The results further demonstrate that human skeletal muscle mitochondria cannot directly oxidize lactate within the mitochondrial matrix. Alternately, these data support previous claims that lactate is converted to pyruvate within the mitochondrial intermembrane space with the pyruvate subsequently taken into the mitochondrial matrix where it enters the TCA cycle and is ultimately oxidized.

The C57Bl/6 mouse serves as a suitable model of human skeletal muscle mitochondrial function

It is debatable whether differences in mitochondrial function exist across skeletal muscle types and whether mouse skeletal muscle mitochondrial function can serve as a valid model for human skeletal muscle mitochondrial function. The aims of this study were to compare and contrast three different mouse skeletal muscles and to identify the mouse muscle that most closely resembles human skeletal muscle respiratory capacity and control. Mouse quadriceps (QUAD(M)), soleus (SOL(M)) and gastrocnemius (GAST(M)) skeletal muscles were obtained from 8- to 10-week-old healthy mice (n = 8), representing mixed, oxidative and glycolytic muscle, respectively. Skeletal muscle samples were also collected from young, active, healthy human subjects (n = 8) from the vastis lateralis (QUAD(H)). High-resolution respirometry was used to examine mitochondrial function in all skeletal muscle samples, and mitochondrial content was quantified with citrate synthase activity. Mass-specific respiration was higher across all respiratory states in SOL(M) versus both GAST(M) and QUAD(H) (P < 0.01). When controlling for mitochondrial content, however, SOL(M) respiration was lower than GAST(M) and QUAD(H) (P < 0.05 and P < 0.01, respectively). When comparing respiratory capacity between mouse and human muscle, QUAD(M) exhibited only one different respiratory state when compared with QUAD(H). These results demonstrate that qualitative differences in mitochondrial function exist between different mouse skeletal muscles types when respiratory capacity is normalized to mitochondrial content, and that skeletal muscle respiratory capacity in young, healthy QUAD(M) does correspond well with that of young, healthy QUAD(H).

Mitochondria: A mirror into cellular dysfunction in heart disease

Cardiovascular (CV) disease is the single most significant cause of morbidity and mortality worldwide. The emerging global impact of CV disease means that the goals of early diagnosis and a wider range of treatment options are now increasingly pertinent. As such, there is a greater need to understand the molecular mechanisms involved and potential targets for intervention. Mitochondrial function is important for physiological maintenance of the cell, and when this function is altered, the cell can begin to suffer. Given the broad range and significant impacts of the cellular processes regulated by the mitochondria, it becomes important to understand the roles of the proteins associated with this organelle. Proteomic investigations of the mitochondria are hampered by the intrinsic properties of the organelle, including hydrophobic mitochondrial membranes; high proportion of basic proteins (pI greater than 8.0); and the relative dynamic range issues of the mitochondria. For these reasons, many proteomic studies investigate the mitochondria as a discrete subproteome. Once this has been achieved, the alterations that result in functional changes with CV disease can be observed. Those alterations that lead to changes in mitochondrial function, signaling and morphology, which have significant implications for the cardiomyocyte in the development of CV disease, are discussed.

Membrane microenvironment regulation of carnitine palmitoyltranferases I and II

CPT (carnitine palmitoyltransferase) 1 and CPT2 regulate fatty acid oxidation. Recombinant rat CPT2 was isolated from the soluble fractions of bacterial extracts and expressed in Escherichia coli. The acyl-CoA chain-length-specificity of the recombinant CPT2 was identical with that of the purified enzyme from rat liver mitochondrial inner membranes. The Km for carnitine for both the mitochondrial preparation and the recombinant enzyme was identical. In isolated mitochondrial outer membranes, cardiolipin (diphosphatidylglycerol) increased CPT1 activity 4-fold and the Km for carnitine 6-fold. It decreased the Ki for malonyl-CoA inhibition 60-fold, but had no effect on the apparent Km for myristoyl-CoA. Cardiolipin also activated recombinant CPT2 almost 4-fold, whereas phosphatidylglycerol, phosphatidylserine and phosphatidylcholine activated the enzyme 3-, 2- and 2-fold respectively. Most of the recombinant CPT2 was found to have substantial interaction with cardiolipin. A model is proposed whereby cardiolipin may hold the fatty-acid-oxidizing enzymes in the active functional conformation between the mitochondrial inner and outer membranes in conjunction with the translocase and the acyl-CoA synthetase, thus combining all four enzymes into a functional unit.

Colocalization of MCT1, CD147, and LDH in mitochondrial inner membrane of L6 muscle cells: evidence of a mitochondrial lactate oxidation complex

Results of previous studies suggested a role of mitochondria in intracellular and cell-cell lactate shuttles. Therefore, by using a rat-derived L6 skeletal muscle cell line and confocal laser-scanning microscopy (CLSM), we examined the cellular locations of mitochondria, lactate dehydrogenase (LDH), the lactate-pyruvate transporter MCT1, and CD147, a purported chaperone protein for MCT1. CLSM showed that LDH, MCT1, and CD147 are colocalized with the mitochondrial reticulum. Western blots showed that cytochrome oxidase (COX), NADH dehydrogenase, LDH, MCT1, and CD147 are abundant in mitochondrial fractions of L6 cells. Interactions among COX, MCT1, and CD147 in mitochondria were confirmed by immunoblotting after immunoprecipitation. These findings support the presence of a mitochondrial lactate oxidation complex associated with the COX end of the electron transport chain that might explain the oxidative catabolism of lactate and, hence, mechanism of the intracellular lactate shuttle.

The effect of respiratory chain impairment of beta-oxidation in rat heart mitochondria

Cardiac ischaemia leads to an inhibition of beta-oxidation flux and an accumulation of acyl-CoA and acyl-carnitine esters in the myocardium. However, there remains some uncertainty as to which esters accumulate during cardiac ischaemia and therefore the site of inhibition of beta-oxidation [Moore, Radloff, Hull and Sweely (1980) Am. J. Physiol. 239, H257-H265; Latipää (1989) J. Mol. Cell. Cardiol. 21, 765-771]. When beta-oxidation of hexadecanoyl-CoA in state III rat heart mitochondria was inhibited by titration of complex III activity, flux measured as 14CO2 release, acid-soluble radioactivity or as acetyl-carnitine was progressively decreased. Low concentrations of myxothiazol caused reduction of the ubiquinone pool whereas the NAD+/NADH redox state was less responsive. Measurement of the CoA and carnitine esters generated under these conditions showed that there was a progressive decrease in the amounts of chain-shortened saturated acyl esters with increasing amounts of myxothiazol. The concentrations of 3-hydroxyacyl and 2-enoyl esters, however, were increased between 0 and 0.2 microM myxothiazol but were lowered at higher myxothiazol concentrations. More hexadecanoyl-CoA and hexadecanoyl-carnitine were present with increasing concentrations of myxothiazol. We conclude that 3-hydroxyacyl-CoA dehydrogenase and acyl-CoA dehydrogenase activities are inhibited by reduction of the ubiquinone pool, and that this explains the confusion over which esters of CoA and carnitine accumulate during cardiac ischaemia. Furthermore these studies demonstrate that the site of the control exerted by the respiratory chain over beta-oxidation is shifted depending on the extent of the inhibition of the respiratory chain.

Rapid preparation of subsarcolemmal and interfibrillar mitochondrial subpopulations from cardiac muscle

1. Subsarcolemmal and interfibrillar mitochondria were prepared with complete recovery from rabbit and porcine heart muscle by upward-flotation during 60 sec of Percoll density gradient centrifugation. 2. Mitochondrial subpopulations were identified and characterized according to buoyant density, electron-microscopy, marker enzyme activities and respiratory performance. 3. ADP-induced state 3-respiration related to latent citrate synthase activity as a marker for structurally intact mitochondria was not significantly different in both mitochondrial subtypes.

Skeletal muscle mitochondrial beta-oxidation of dicarboxylates

(1) The oxidation of [U-14C]hexadecanedionoyl-mono-CoA by rat skeletal muscle mitochondrial fractions is carnitine dependent and is inhibited by cyanide. (2) [U-14C]hexadecanedionoyl-mono-CoA was oxidised at a rate 8% of that of [U-14C]hexadecanoyl-CoA. (3) Oxidations were saturable and no substrate inhibition was observed. (4) We demonstrate the formation of dicarboxylyl-mono-CoA esters and the corresponding carnitine derivatives. (5) We conclude that, although skeletal muscle mitochondria are capable of the beta-oxidation of dicarboxylic acids, this is unlikely to be of great physiological significance.

Investigation of glycosylation processes in mitochondria and microsomal membranes from human skeletal muscle

Glycoconjugates are directly involved in major skeletal muscle functions. As little is known about glycosylation processes in muscle, we investigated glycoconjugate synthesis in subcellular fractions from human skeletal muscle tissue. Mitochondria and microsomal membranes were prepared from muscle biopsies by thorough mechanical disruption and differential centrifugations. This procedure resulted in the isolation of intact mitochondria (1 mg protein/g muscle) and of a microsomal fraction (1.5 mg protein/g muscle). Glycosyltransferases were studied in both subcellular fractions using either dolichylmonophosphate as a polyprenic acceptor or chemically modified fetuin as a glycoprotein substrate. Our results provide evidence for high rates of glycosylation in muscle. The highest activities were obtained with GDP-mannose: dilichylmonophosphate mannosyltransferase, a key enzyme in glycosylation process (220 pmol/mg per h in mitochondria and 1,550 pmol/mg per h in microsomal membranes). Substantial individual variations were observed for dolichol pathway glycosyltransferases but low individual variations were found for glycosyltransferases involved in maturation of glycoproteins. The role which glycosylation defects may play in muscle dysfunction has yet to be defined.

A sensitive method for measuring ATP-formation in rat muscle mitochondria

A sensitive method for the measurement of the ATP production rate in isolated skeletal muscle mitochondria is presented. Mitochondrial suspensions were prepared by differential centrifugation from approximately 80 mg of soleus muscle. ATP production rates were measured luminometrically, utilizing a reagent based upon firefly luciferase, which emits light proportional to the ATP concentration. In a group of 10 rats the ATP production rates were measured with the following substrate combinations: pyruvate + malate, palmitoyl-L-carnitine + malate, alpha-ketoglutarate, succinate + rotenone and succinate alone. The variance of the method including tissue preparation, protein determination and the luminometric determination of ATP production was estimated to be 10-14% for the various substrates. Compared to values in the literature, the present results show a good agreement for the substrates pyruvate + malate and palmitoyl-L-carnitine + malate, but lower rates were obtained in our study for alpha-ketoglutarate and succinate + rotenone. The advantage of the luminometric method is its high sensitivity. Only 30-40 mg of tissue is required for a complete determination, compared to 1-2 g for a similar assay of oxygen consumption. The method is intended for use in human subjects and will facilitate studies of mitochondrial respiration both in patients of different age groups and in healthy subjects.

Pathway of alpha-linolenic acid through the mitochondrial outer membrane in the rat liver and influence on the rate of oxidation. Comparison with linoleic and oleic acids

The movement of alpha-linolenic acid (C18:3, n-3) through the mitochondrial outer membrane to oxidation sites was studied in rat liver and compared with the movement of linoleic acid (C18:2, n-6) and oleic acid (C18:1, n-9). All differ in the degree of unsaturation, but have the same chain length and the same position of the first double bond when counted from the carboxyl end. The following results were obtained. (1) The overall beta-oxidation in total mitochondria was in the order C18:3, n-3 greater than C18:2, n-6 greater than C18:1, n-9, independent of the amount of albumin in the medium. (2) The rate of formation of acylcarnitine from acyl-CoA was higher with oleoyl-CoA than with linoleoyl-CoA, and remained very low with alpha-linolenoyl-CoA for all concentrations studied. (3) When the formation of acylcarnitines originated from fatty acids (as potassium salts) in a medium containing CoA and ATP, the conversion of alpha-linolenate was greater than that of linoleate, which in turn was greater than that of oleate. (4) Use of a more purified mitochondrial fraction, practically devoid of peroxisomes, did not modify the results obtained with alpha-linolenate. (5) alpha-Linolenoyl-CoA did not inhibit oxidation of labelled alpha-linolenate, whereas the other acyl-CoAs did. (6) Transfer to carnitine of all three fatty acids (as potassium salts) by carnitine palmitoyltransferase-I (CPT-I) was similarly inhibited by increasing concentrations of malonyl-CoA. (7) On using a fraction containing mitochondrial outer membranes, the formation of acylcarnitines from potassium salts of fatty acids was qualitatively and quantitatively similar to that found with whole mitochondria. (8) Our observations show that alpha-linolenoyl-CoA synthesized other than in the mitochondria cannot be used to any great extent by the mitochondria due to its configuration. However when added as the unactivated form, alpha-linolenate appears to be very quickly oxidized, but should first be activated by acyl-CoA synthetase in the mitochondrion itself. Then it is rapidly channelled to CPT-I. These enzymic sites are probably close together in the mitochondrial outer membrane. The different behaviour of the alpha-linolenic group compared with the other acyl groups in the studied pathway can be explained by a different spatial arrangement due to the number and position of the double bonds.

Skeletal muscle mitochondrial beta-oxidation. A study of the products of oxidation of [U-14C]hexadecanoate by h.p.l.c. using continuous on-line radiochemical detection

Well-coupled mitochondrial fractions were prepared from rat skeletal muscle without the use of proteolytic enzymes. The products of [U-14C]hexadecanoate oxidation by rat skeletal muscle mitochondrial fractions were analysed by h.p.l.c. with on-line radiochemical detection. In the presence of 1 mM-carnitine, 70% of the products is acetylcarnitine. In agreement with Veerkamp et al. [Veerkamp, van Moerkerk, Glatz, Zuurveld, Jacobs & Wagenmakers (1986) Biochem. Med. Metab. Biol. 35, 248-259] 14CO2 release is shown to be an unreliable estimate of flux through beta-oxidation in skeletal muscle mitochondrial fractions. The flux through beta-oxidation is recorded unambiguously polarographically in the presence of 1 mM-carnitine and the absence of citrate cycle intermediates.

Some differences in the properties of carnitine palmitoyltransferase activities of the mitochondrial outer and inner membranes

Recent evidence has shown that the outer, overt, malonyl-CoA-inhibitable carnitine palmitoyltransferase (CPTo) activity resides in the mitochondrial outer membrane [Murthy & Pande (1987) Proc. Natl. Acad. Sci. U.S.A. 84, 378-382]. A comparison of CPTo activity of rat liver mitochondria with the inner, initially latent, carnitine palmitoyltransferase (CPTi) of the mitochondrial inner membrane has revealed that the presence of digitonin and several other detergents inactivates CPTo activity. The CPTi activity, in contrast, was markedly stimulated by various detergents and phospholipid liposomes. These findings explain why in previous studies, which used digitonin or other detergents to expose, separate and purify the CPT activities, the inferences were drawn that (a) the ratio of latent to overt CPT was quite high, (b) both the CPT activities could be ascribed to one active protein recovered, and (c) the observed lack of malonyl-CoA inhibition indicated possible loss/separation of a putative malonyl-CoA-inhibition-conferring protein. Although both CPTo and CPTi were found to catalyse the forward and the backward reactions, CPTo showed greater capacity for the forward reaction and CPTi for the backward reaction. The easily solubilizable CPT, released on sonication of mitoplasts or of intact mitochondria under hypo-osmotic conditions, resembled CPTi in its properties. When octyl glucoside was used under appropriate conditions, 40-50% of the CPTo of outer membranes became solubilized, but it showed limited stability and decreased malonyl-CoA sensitivity. Malonyl-CoA-inhibitability of CPTo was decreased also on exposure of outer membranes to phospholipase C. When outer membranes that had been exposed to octyl glucoside or to phospholipase C were subjected to a reconstitution procedure using asolectin liposomes, the malonyl-CoA-inhibitability of CPTo was restored. A role of phospholipids in the malonyl-CoA sensitivity of CPTo is thus indicated.

Should nagarse be used during the isolation of brain mitochondria?

When nagarse is used to isolate brain mitochondria, a proportion of the nagarse stays associated with the mitochondrial fraction. This results in no detrimental affect on the respiratory activities. The nagarse is active in the presence of 2.3% sodium dodecyl sulfate and when samples are prepared for sodium dodecyl sulfate-polyacrylamide gel electrophoresis in the presence of sodium dodecyl sulfate, the nagarse degrades a substantial amount of the mitochondrial proteins.

Malonyl-CoA binding site and the overt carnitine palmitoyltransferase activity reside on the opposite sides of the outer mitochondrial membrane

The overt carnitine palmitoyltransferase (palmitoyl-CoA:L-carnitine O-palmitoyltransferase, EC 2.3.1.21) activity of intact mitochondria from rat heart and liver was found to be resistant to the action of proteases such as Nagarse (subtilisin, EC 3.4.21.14). Nagarse under the same conditions, however, greatly decreased the malonyl-CoA inhibition of carnitine palmitoyltransferase activity, the high-affinity binding of malonyl-CoA to mitochondria, and the ability of malonyl-CoA to shift to the right the sigmoid activity curve of carnitine palmitoyltransferase observed with variations in palmitoyl-CoA concentration. No noticeable effect of Nagarse pretreatment was observed on the binding of octanoyl-CoA to mitochondria. Subfractionation of liver mitochondria using a combination of swelling, shrinking, and density gradient centrifugation yielded a membrane fraction in which the specific activities of the outer membrane marker enzymes were enriched greater than or equal to 16-fold together with a near-parallel enrichment of malonyl-CoA-inhibitable carnitine palmitoyltransferase activity. The percent recovery of this carnitine palmitoyltransferase in the outer membrane vesicles also matched that of the known outer membrane markers. The carnitine palmitoyltransferase activity of these out-side-out vesicles became susceptible to added Nagarse only on their cosonication. These findings show that whereas the malonyl-CoA binding site relevant to the inhibition of carnitine palmitoyltransferase is situated on the outer side of the outer membrane, the overt carnitine palmitoyltransferase activity resides on the inner side of the outer membrane.

Modified properties of hexokinase from heart mitochondria prepared using proteolytic enzyme

Isolation of muscle mitochondria is made easier by using proteolytic treatment of the tissue before homogenization. Normally, the proteolytic enzyme is discarded with the supernatant of the first centrifugation. However, our results show that a fraction of enzyme activity remains associated with mitochondria. As shown in experiments described in this paper, mitochondrial hexokinase from tissue treated or not with the proteolytic enzyme exhibits similar properties except that the solubilized enzyme from protease treated tissue is no longer able to rebind to mitochondrial membrane. This modification of the binding ability of the enzyme results from a partial hydrolysis of hexokinase during solubilization experiments by the proteolytic enzyme. Since, as pointed out here, proteolytic enzyme can remain associated with mitochondria, [either absorbed on mitochondrial membrane or included in the mitochondrial pellet] its use for the isolation of muscle mitochondria should be avoided.

Biochemical and morphological study of cardiac hypertrophy. Effects of thyroxine on enzyme activities in the rat myocardium

Experimental hyperthyroidism induced in rats by daily injections of 3,3',5,5'-tetraiode-L-thyroxine (0.5 mg/kg i.p.) for 14 days resulted in a significant increase in heart weight and heart weight/body weight ratio. Hemodynamic and morphological studies were performed in one group. Thyroxine-treated rats showed a characteristic cardiovascular hyperdynamic state, such as tachycardia and augmented rate of contraction, but no evidence of heart failure such as elevated end-diastolic pressures. The cardiac cells in hyperthyroid rats had a significantly larger diameter and more mitochondria than did those of the control rats. In another group the activities of cardiac enzymes involved in energy utilization and liberation were measured biochemically and compared with those of normal controls. Hyperthyroidism resulted in increased specific activity of cytochrome C oxidase and actomyosin ATPase in the myocardium. The specific activity of long-chain acyl-CoA synthetase, carnitine palmityl-transferase, carnitine acetyltransferase, malate dehydrogenase and citrate synthase showed a moderate to marked increment, whereas the specific activity of lactate dehydrogenase and pyruvate kinase remained at the control values. These results suggest that in hyperthyroid rat hearts the functions of both energy liberation and utilization systems are enhanced to meet the added workload. Moreover, the increased activity of the enzymes participating in fatty acid metabolism suggest that in thyroxine-induced hypertrophic and hyperdynamic rat hearts, fatty acids contribute more to the energy supply than do carbohydrates.

Biochemical differences between subsarcolemmal and interfibrillar mitochondria from rat cardiac muscle: effects of procedural manipulations

Differences in oxidative metabolism between subsarcolemmal and interfibrillar heart mitochondria were investigated. Interfibrillar mitochondria oxidized substrates donating reducing equivalents at Complex I (NADH-CoQ reductase), Complex II (succinate-CoQ reductase), and Complex III (CoQH2-cytochrome c reductase) more rapidly than did subsarcolemmal mitochondria. There was no difference in oxidation of substrates entering the electron transport chain at Complex IV (cytochrome c oxidase). Differences expressed in normal-ionic-strength medium at Complexes II and III but not I were eliminated in low-ionic-strength medium. The concentrations of cytochromes and activities of NADH and cytochrome c oxidase were virtually the same in the two populations. In permeabilized mitochondria, activities of succinate-duroquinone and TMPD plus ascorbate oxidase were significantly lower in the subsarcolemmal mitochondria. Differences in membrane permeability between the populations were suggested by the greater permeability of subsarcolemmal mitochondria to exogenous NADH. The influence of isolation buffers and preparative procedures on the two classes of mitochondria were also examined. Characteristic biochemical and morphological properties of the two populations were unchanged by exposing each to the preparative procedure used to isolate the alternate population; the oxidative performance of the two populations cannot be equalized by experimental manipulation.

Oxidative metabolism of Polytron versus Nagarse mitochondria in hearts of genetically diabetic mice

We have shown previously that heart mitochondria obtained by the Nagarse method from genetically diabetic mice (C57BL/KsJ db/db) exhibit a defect in oxidizing NAD+-linked substrates (Kuo, T.H., Moore, K.H., Giacomelli, F. and Wiener, J. (1983) Diabetes 32, 781-787). In this study, the oxidative phosphorylation characteristics of cardiac mitochondria isolated by the Polytron method were compared with that of Nagarse mitochondria. Evidence is presented here that in the diabetic heart both Nagarse and Polytron mitochondria have defective pyruvate oxidation, whereas only the former exhibit impaired fatty acid oxidation. Assay of two rate-limiting beta-oxidation enzymes, namely beta-hydroxyacyl-CoA dehydrogenase and beta-ketothiolase, indicates no alteration in specific activities from diabetic mice vs. controls. The data suggest that two populations of mitochondria are present in myocardium and that the defective oxidative metabolism in the cardiac mitochondria of db/db mice may be linked to deficiencies in total NAD + NADH content.

Investigation of mitochondrial metabolism in small human skeletal muscle biopsy specimens. Improvement of preparation procedure

A method is presented which allows the investigation of almost the complete mitochondrial content of small human skeletal muscle biopsy specimens. Thorough mechanical disruption with a chopper apparatus results in the release of about 50% of the mitochondrial content. Subsequent treatment of the 600 x g sediment with trypsin releases another 30% of the total mitochondrial population. The biochemical characteristics of the two mitochondrial fractions obtained in these two successive steps have been compared. No obvious differences could be established. The procedure is well suited for biochemical investigation of muscle biopsy specimens from patients suspected of suffering from a mitochondrial myopathy.

Different respiratory activities of mitochondria isolated from the subendocardium and subepicardium of the canine heart

Mitochondria were prepared from the subendocardial and subepicardial layers of the canine left ventricle. The oxidation rates of palmitate, palmitoyl carnitine and pyruvate of the mitochondria obtained from the two cardiac layers were measured. The cytochrome content and the specific activities of different beta oxidation and Krebs cycle enzymes were also measured in the two mitochondrial populations. Mitochondria isolated from the ENDO layer showed significantly higher oxidation rates than mitochondria from the EPI layer for all the three substrates. No statistically significant differences in cytochrome c+c1 and a+a3 content were found in mitochondria isolated from the two regions. No significant transmural differences were found in fatty acyl CoA, L-3-hydroxy fatty acyl CoA, succinic and malic dehydrogenase specific activities, whilst isocitric dehydrogenase (NADP) specific activity was significantly higher in mitochondria isolated from the inner layer. In conclusion, the mitochondria isolated from the inner left ventricular layer of the canine heart show a higher oxidative capacity than subepicardial mitochondria. This difference could partly be explained by the higher specific activity of isocitric dehydrogenase in this layer. These properties of subendocardial mitochondria could represent a metabolic support for the greater contractile performance of this layer.

Uptake, retention, and efflux of Ca2+ by mitochondrial preparations from skeletal muscle

Functionally intact mitochondria, substantially free of contamination, were isolated from rabbit gastrocnemius muscle after protease digestion and their Ca2+-handling properties examined. When judged by their capacity to retain large Ca2+ loads and the magnitude of basal and Na+-stimulated Ca2+ effluxes, the most suitable isolation method was digestion of finely minced muscle in buffered isoosmotic KCl with low levels (0.4 mg/g) of trypsin or the bacterial protease nagarse, followed by differential centrifugation. Polytron disruption of skeletal muscle in both sucrose- and KCl-based media released mitochondria deficient in cytochrome c. Use of the divalent ion chelator EDTA rather than EGTA in the isolation medium sharply reduced Ca2+-dependent respiratory control and tolerance of the mitochondria to Ca2+ loads, probably by removing Mg2+ essential to membrane integrity. ADP-dependent respiratory control was not altered in mitochondria prepared in an EDTA-containing isolation medium. Purification of mitochondria on a Percoll density gradient did not improve their Ca2+-handling ability despite removal of minor contaminants. Mitochondria prepared by the protease method could accumulate micromole loads of Ca2+/mg while maintaining a low basal Ca2+ efflux. Addition of BSA to the assay medium slightly improved Ca2+ retention but was not essential either during isolation or assay. Ca2+-dependent state 3 respiration was maximal at pH 6.5-7.0 while respiratory control and Ca2+/O were optimal at pH 7.0-7.5. Neither Pi nor oxaloacetate induced Ca2+ release from loaded mitochondria when monitored for 30 min after ruthenium red addition. Na+-stimulated Ca2+ efflux had sigmoidal kinetics with a Hill coefficient of 3. Since skeletal muscle mitochondria can be isolated and assayed in simple media, functional deficiencies of mitochondria from diseased muscle are unlikely to be masked.

Acyl-CoA synthetase activity of rat heart mitochondria. Substrate specificity with special reference to very-long-chain and isomeric fatty acids

The acyl-CoA synthetase (acid: CoA ligase (AMP-forming), EC 6.2.1.3) activity of rat heart has been measured in fatty acid-depleted fractions of mitochondria, microperoxisomes and microsomes. The assay was based on (i) the measurement of the reaction product AMP by high-performance liquid chromatography or (ii) a coupled reaction in which the intramitochondrial (matrix) CoASH is the final acyl acceptor and the redox state of the flavoproteins in the acyl-CoA dehydrogenase pathway is used to determine the intramitochondrial level of acyl-CoA. This spectrophotometric method was also used to estimate the 'outer' carnitine long-chain acyltransferase (palmitoyl-CoA:L-carnitine O-palmitoyltransferase, EC 2.3.1.21) activity. Comparison of the distribution of long-chain acyl-CoA synthetase activity and marker enzymes in the various subcellular fractions revealed that the synthetase activity is exclusively localized in the mitochondrial fraction. Experimental evidence is presented in support of the conclusion that the chain-length specificity of saturated and monounsaturated fatty acids (16:1-22:1) for the acyl-CoA synthetase is mainly determined by the availability of the fatty acid at the active site, which is largely determined by the affinity of binding of fatty acids to the bulk phase of the mitochondrial phospholipids. Among the 22:1 isomers, 22:1(11) (cis) (cetoleic acid) revealed a slightly higher activity (1.4-fold) than 22:1(13) (cis) (erucic acid). The polyunsaturated fatty acids tested were rather poor substrates. Using isolated intact mitochondria and 16:0 or 22:1(13) (cis) as the substrates, it was found that the initial rate of the 'outer' long-chain acyltransferase activity was approximately four times higher than that of the long-chain acyl-CoA synthetase. The data support the hypothesis that the long-chain acyl-CoA synthetase reaction is rate-limiting in the sequence of coupled reactions leading to beta-oxidation in the mitochondrial matrix.

Cytochrome c oxidase activity and fatty acid oxidation in various types of human muscle

Cytochrome c oxidase activity, carnitine concentration and oxidation rates of pyruvate and palmitate were determined in homogenates of various types of human skeletal muscle. Cytochrome c oxidase activity appeared to be closely related to the pyruvate oxidation rate, but its correlation with palmitate oxidation was less distinct. Trunk muscles oxidize less palmitate and have a lower cytochrome c oxidase activity per mg homogenate protein than leg muscles; soleus muscle biopsies showed higher activities than those of other leg muscles. Based on cytochrome c oxidase activity no large differences are found in palmitate oxidation rate between various types of human muscle. Cytochrome c oxidase activity and palmitate oxidation rate of muscles do not show an age dependency. The carnitine concentration is similar in all kinds of human skeletal muscle.

Early changes of muscle mitochondria in Duchenne dystrophy. Partition and activity of mitochondrial enzymes in fractionated muscle of unaffected boys and adults and patients

(1) Biopsies from the gastrocnemius muscle of patients with Duchenne dystrophy were partitioned into a myofibrillar plus nuclear fraction, a mitochondrial fraction and a supernatant fraction. The fractions were assayed for mitochondrial enzymes and protein, in order to obtain information about the integrity of mitochondrial structure and function. Muscles from boys and adults without neuromuscular disease were treated likewise. (2) In adults, muscle possesses a significantly higher specific activity (on protein basis) of monoamine oxidase and rotenone-insenitive NADH-cytochrome c reductase (RINCR) than in boys. In childhood, monoamine oxidase activity increases with age. At the age of 5 yr, the specific activity is 50% of the adult value. RINCR activity is constant in childhood. With adolescence it increases from 20 +/- 2 (SEM) to 35 +/- 6 mumoles cytochrome c reduced per min per g protein, and it remains at this level. Palmitoyl-CoA synthetase activity remains constant with age. (3) In Duchenne dystrophy the extractable protein content from muscle is decreased to 75%. The specific activities of the matrix enzymes propionyl-CoA carboxylase and glutamate dehydrogenase are 1.8 and 2.8 times increased, the inner membrane enzyme cytochrome c oxidase is 2.8 times increased, the inner membrane enzyme cytochrome c oxidase is 2.8 times increased. Of the outer membrane enzymes RINCR is 2.0 times increased, while palmitoyl-CoA synthetase is not changed in acitivity. In Duchenne dystrophy monoamine oxidase activity also increases with age. In part this may be due to mitochondria from adipose tissue and macrophages, which are increasingly present in older patients. The specific activities of enzymes with a predominant cytosolic localisation, creatine kinase and adenylate kinase, are increased by a factor of 1.5 and 1.7. (4) The subcellular distribution of the studied enzymes in human skeletal muscle was found to be similar as in animal studies. In mitochondrial fractions from Duchenne patients the recoveries of the following enzymes are decreased: glutamate dehydrogenase (from 25 to 9%), creatine kinase (1.1-0.66%), adenylate kinase (0.44-0.22%), hexokinase (7.1-2.7%), monoamine oxidase (36-21%), RINCR (30-17%), and palmitoyl-CoA synthetase (40-21%). The recoveries of last 3 mitochondrial outer membrane enzymes in the supernatant fractions are correspondingly increased. These results indicate an increased fragility of the mitochondrial membranes in dystrophic muscles. (5) The reported changes are clearly evident in a one-year-old patient, which indicates that the mitochondria are involved early in the disease process.

Familial carnitine deficiency. A fatal case and subclinical state in a sister

A 15-year-old girl with a large accumulation of lipid in the muscle fibers, was suffering from systemic carnitine deficiency. She died in acidosis. The blood carnitine level was normal. At necropsy, carnitine levels were low in skeletal muscles and heart, whilst a normal level was found in the liver. Carnitine palmitoyltransferase II and palmitoyl-CoA synthetase activities were increased, whereas carnitine acetyltransferase, glycerol-3-phosphate dehydrogenase (FAD) and succinate dehydrogenase were decreased. Investigation of blood and skeletal muscle of the family members revealed marked abnormalities in a 7-year old sister who had only minor neurological symptoms. Histochemical investigation revealed abnormal accumulations of lipid between the myofibrils. Carnitine was decreased in her skeletal muscle and blood. Muscular carnitine palmitoyltransferase II and palmitoyl-CoA synthetase were again increased in activity while glycerol-3-phosphate dehydrogenase (FAD) was decreased. The activities of succinate dehydrogenase, carnitine palmitoyltransferase I and glycerol-3-phosphate dehydrogenase (NAD+) were normal. The unexpected normal carnitine level in blood and liver of the deceased patient was attributed to muscle wasting, which was confirmed by the very high blood level of creatine phosphokinase. This fatal case indicates that the fasting condition must be avoided in persons with carnitine deficiency. In crises, glucose supply is necessary since gluconeogenesis may be blocked.

Carnitine palmitoyltransferase II deficiency with normal carnitine palmitoyltransferase I in skeletal muscle and leucocytes

Deficiency of carnitine palmitoyltransferase II (CPT II), was found to be the cause of the syndrome of muscle pain and myoglobinuria following strenuous exercise in an otherwise healthy young man. During fasting, serum creatine kinase remained low and ketogenesis was normal. The clearance of a fat emulsion and the activity of extrahepatic lipoprotein lipase was lowered, while the hepatic lipoprotein lipase was normal. A skeletal muscle biopsy did not show abnormal lipid storage. CPT II was deficient in skeletal muscle and leucocytes, while CPT I activity was normal and exhibited normal kinetic properties. CPT I has a higher affinity for palmitoylcarnitine than CPT II, and is more inhibited at increasing palmitoylcarnitine concentrations. In erythrocytes only CPT I is present.

Biochemical and morphological correlates of acute experimental myocardial ischemia in the dog. IV. Energy mechanisms during very early ischemia

Tissue energy metabolism was examined in posterior (ischemic) and anterior ("control") regions of canine ventricles after 5 and 10 minutes of left circumflex coronary artery occlusion. When compared to identical regions of normal hearts, the following changes were found: (1) decreases in glycogen and phosphorylase activity in the anterior and posterior regions, (2) depressed state 3 rates of oxygen consumption of isolated mitochondria in both anterior and posterior regions, (3) shifts in optimum substrate concentrations for palmityl-CoA (+ carnitine) oxidation by mitochondria in the anterior and posterior regions, and (4) decreases in the apparent zero order and first order rates of mitochondrial palmitylcarnitine production. These changes correlated with a marked decrease in developed tension in the posterior regions. Depression in tension development in the posterior regions of the heart still was present after 30--60 minutes of reperfusion following a 10-minute period of occlusion. Glycogen content in the reperfused areas was significantly decreased after 60 minutes of reperfusion when compared to normal areas and to control hearts perfused for 70 minutes. After reperfusion, mitochondrial function appeared to return toward "normal." However, the slow restoration of contraction of the ischemic area suggests that cellular mechanisms operative in vivo to restore pump function still might be abnormal.

The oxidation of long-chain unsaturated fatty acids by isolated rat liver mitochondria as a function of substrate concentration

1. The oxidation of linoleate by rat-liver mitochondria has been studied as a function of substrate concentration. The oxidation of other long-chain unsaturated fatty acids shows similar characteristics. 2. At low concentrations, linoleate is readily oxidized in the absence of carnitine. Its rate of activation by the intramitochondrial acyl-CoA synthetase (EC 6.2.1.2) and subsequent oxidation is limited by the availability of intra-mitochondrial ATP. 3. A gradual increase of the linoleate concentration leads to (i) a strong depression of the rate of linoleate oxidation, and (ii) uncoupling of respiratory-chain phosphorylation together with induction of a mitochondrial ATPase activity. At still higher linoleate concentrations this ATPase activity is lowered rather than further stimulated and, concomitantly, the rate of linoleate oxidation increases again. 4. Evidence is presented that the inhibition by linoleate of the ATPase activity occurs at the level of the ATPase complex itself. This oligomycin-like effect of linoleate allows intramitochondrial linoleate activation to take place at the expense of ATP derived from substrate-level phosphorylation. 5. At very high concentrations of linoleate, its detergent action predominates and causes a complete inhibition of respiration as well as an extensive stimulation of an oligomycin-insensitive, Mg2+-dependent ATPase activity. 6. Measurement of the binding of radioactively labelled linoleate by isolated mitochondria shows that, at a given ratio of linoleate to mitochondrial protein, the ratio of bound to added linoleate is dependent on the concentration of the mitochondria.

Effect of chronic hypoxia on hepatic triacylglycerol concentration and mitochondrial fatty acid oxidizing capacity in liver and heart

The effect of moderated hypoxia (50.5 kPa air) and severe hypoxia (40.8 kPa air) in vivo liver and heart triglyceride concentration and mitochondrial respiration rates was studied. Liver triglyceride concentrations increased in severe hypoxia from 7.3 mumol/g wet weight to 23.3 mumol/g wet weight over 7 days. After the period of seven days in severe hypoxia, the palmitate, octanoate and palmitoylcarnitine oxidation rates of mitochondrial suspensions were significantly reduced when the citric acid cycle was operative. No decrease in the fatty acid, fatty acyl-CoA or carnitine derivative oxidation was observed when only the beta oxidation system was studied. Mitochondria isolated from the heart or liver after seven days in severe hypoxia showed reduced respiratory control ratios, the decrease being from the normal 4.9 to 1.9 in the liver mitochondria using succinate as substrate. The reduction in respiratory control was mainly due to lowered State 3 respiration rates. Some reduction in the ratio was also observed in the fasting controls, from 5.8 to 3.4 with succinate. The respiratory control ratio could be partially normalized by the addition of albumin to the isolation medium for the liver mitochondria after severe hypoxia. Under these conditions, however, the State 4 respiration of the mitochondria from the hypoxic animals was higher than that for the controls.

The effect of palmitoyl-coenzyme A on rat heart and liver mitochondria. Oxygen consumption and palmitoylcarnitine formation

Rat heart and liver mitochondria, respectively, oxidized palmitoyl-CoA and palmitoylcarnitine optimally at 20-30 and 10-20 nmol substrate/mg. The oxidation of palmitoyl-CoA was accompanied by a lag in State 3 respiration that was proportional to the palmitoyl-CoA concentration. The delay in State 3 rates was more prolonged in liver than in heart at comparable palmitoyl-CoA levels. A similar range of palmitoyl-CoA concentrations produced significant inhibition of respiration in mitochondria oxidizing glutamate-malate. The inhibition was not due to a detergent effect of palmitoyl-CoA since addition of carnitine restored State 3 rates. Electron microscopic examination of mitochondria at low palmitoyl-CoA levels revealed normal ultrastructure. At comparable concentrations of palmitoyl-CoA, formation of palmitoylcarnitine by mitochondria from rat heart and liver followed first-order kinetics. The apparent first-order rate constants decreased with increasing palmitoyl-CoA. These results suggest that substrate inhibition may influence the rate of palmitoyl carnitine formation even at physiological concentrations of palmitoyl-CoA. The apparent first-order rate constant at palmitoyl-CoA levels (12 nmol palmitoyl CoA/mg) optimally oxidized by liver mitochondria, was one-third the value of the apparent rate constant measured in heart mitochondria at the identical substrate level. The prolongation in time to reach equilibrium may acocunt for the relatively greater respiratory sensitivity of liver mitochondria to increasing levels of palmitoyl-CoA.