Cysteine protease activity of feline Tritrichomonas foetus promotes adhesion-dependent cytotoxicity to intestinal epithelial cells.

Trichomonads are obligate protozoan parasites most renowned as venereal pathogens of the reproductive tract of humans and cattle. Recently, a trichomonad highly similar to bovine venereal Tritrichomonas foetus but having a unique tropism for the intestinal tract was recognized as a significant cause of colitis in domestic cats. Despite a high prevalence, worldwide distribution, and lack of consistently effective drugs for treatment of the infection, the cellular mechanisms of T. foetus pathogenicity in the intestinal tract have not been examined. The aims of this study were to determine the pathogenic effect of feline T. foetus on porcine intestinal epithelial cells, the dependence of T. foetus pathogenicity on adhesion of T. foetus to the intestinal epithelium, and the identity of mediators responsible for these effects. Using an in vitro coculture approach to model feline T. foetus infection of the intestinal epithelium, these studies demonstrate that T. foetus promotes a direct contact-dependent activation of intestinal epithelial cell apoptosis signaling and progressive monolayer destruction. Moreover, these pathological effects were demonstrated to be largely dependent on T. foetus cell-associated cysteine protease activity. Finally, T. foetus cysteine proteases were identified as enabling cytopathic effects by promoting adhesion of T. foetus to the intestinal epithelium. The present studies are the first to examine the cellular mechanisms of pathogenicity of T. foetus toward the intestinal epithelium and support further investigation of the cysteine proteases as virulence factors in vivo and as potential therapeutic targets for ameliorating the pathological effects of intestinal trichomonosis.

The role of mitochondrial function and cellular bioenergetics in ageing and disease.

Mitochondria constitute an important topic of biomedical enquiry (one paper in every 154 indexed in PubMed since 1998 is retrieved by the keyword 'mitochondria') because of widespread recognition of their importance in cell physiology and pathology. Mitochondrial dysfunction is widely implicated in ageing and in the diseases of ageing, through dysfunction in adenosine triphosphate (ATP) synthesis, Ca(2+) homeostasis, central metabolic pathways or radical production. Nonetheless, the mechanisms and regulation of superoxide and hydrogen peroxide formation by mitochondria remain poorly described. Measurement of the capacities of different sites of superoxide and hydrogen peroxide production in isolated skeletal muscle mitochondria show that the maximum capacities of sites in complexes I, II and III and in several associated redox enzymes greatly exceed the native rates observed in the absence of respiratory chain inhibitors. In vitro, the native rates and the relative importance of different sites both depend on the substrate being oxidized, with sites IQ, IIF, GPDH, IF and IIIQo each being important with particular substrates. The techniques involved in measuring rates from each site should become applicable to cell cultures and in vivo in the future.

Mitochondrial uncoupling protein 2 in pancreatic ß-cells.

Pancreatic ß-cells have remarkable bioenergetics in which increased glucose supply upregulates the cytosolic ATP/ADP ratio and increases insulin secretion. This arrangement allows glucose-stimulated insulin secretion (GSIS) to be regulated by the coupling efficiency of oxidative phosphorylation. Uncoupling protein 2 (UCP2) modulates coupling efficiency and may regulate GSIS. Initial measurements of GSIS and glucose tolerance in Ucp2(-/-) mice supported this model, but recent studies show confounding effects of genetic background. Importantly, however, the enhancement of GSIS is robustly recapitulated with acute UCP2 knockdown in INS-1E insulinoma cells. UCP2 protein level in these cells is dynamically regulated, over at least a fourfold concentration range, by rapid proteolysis (half-life less than 1 h) opposing regulated gene transcription and mRNA translation. Degradation is catalysed by the cytosolic proteasome in an unprecedented pathway that is currently known to act only on UCP2 and UCP3. Evidence for proteasomal turnover of UCP2 includes sensitivity of degradation to classic proteasome inhibitors in cells, and reconstitution of degradation in vitro in mitochondria incubated with ubiquitin and the cytosolic 26S proteasome. These dynamic changes in UCP2 content may provide a fine level of control over GSIS in ß-cells.

Mitochondrial proton leak kinetics and relationship with feed efficiency within a single genetic line of male broilers.

Studies were conducted to assess proton leak kinetics (proton conductance) in breast muscle mitochondria isolated from broiler breeder males within a single genetic line exhibiting either high (HFE) or low (LFE) feed efficiency. Proton leak kinetics were determined by simultaneously measuring mitochondrial membrane potential and state 2 (resting) respiration rate in breast muscle mitochondria as succinate oxidation was progressively decreased by malonate. Control proton conductance was similar in HFE and LFE mitochondria and decreased to a similar extent in both groups in response to BSA. Although treatment of mitochondria with Glu or guanosine diphosphate had no effect, retinal increased and carboxyatractylate alone or in combination with Glu decreased proton conductance relative to control proton conductance in both HFE and LFE mitochondria. After treatment with either guanosine diphosphate or carboxyatractylate alone, proton conductance was lower in HFE compared with LFE mitochondria. With the exception of BSA, proton conductance in HFE mitochondria after the various chemical treatments was either less than or equal to, and never greater than, proton conductance in the LFE mitochondria. The results suggest that there are subtle differences in membrane characteristics (e.g., lipids, integral membrane proteins) that affect proton conductance in broiler muscle mitochondria that may in turn play a role in the phenotypic expression of feed efficiency.

The proton leak across the mitochondrial inner membrane.

The proton conductance of the mitochondrial inner membrane increases at high protonmotive force in isolated mitochondria and in mitochondria in situ in rat hepatocytes. Quantitative analysis of its importance shows that about 20-30% of the oxygen consumption by resting hepatocytes is used to drive a heat-producing cycle of proton pumping by the respiratory chain and proton leak back to the matrix. The flux control coefficient of the proton leak pathway over respiration rate varies between 0.9 and zero in mitochondria depending on the rate of respiration, and has a value of about 0.2 in hepatocytes. Changes in the proton leak pathway in situ will therefore change respiration rate. Mitochondria isolated from hypothyroid animals have decreased proton leak pathway, causing slower state 4 respiration rates. Hepatocytes from hypothyroid rats also have decreased proton leak pathway, and this accounts for about 30% of the decrease in hepatocyte respiration rate. Mitochondrial proton leak may be a significant contributor to standard metabolic rate in vivo.

A quantitative assessment of the use of 36Cl- distribution to measure plasma membrane potential in isolated hepatocytes.

The plasma membrane potential of isolated rat hepatocytes was clamped at different values between 0 and -68 mV by addition of valinomycin in the presence of different extracellular concentrations of K+, and measured by the distribution of 86Rb+ between cells and medium. 36Cl- distribution came to steady state in 10-15 min. This steady-state distribution was compared to the plasma membrane potential over a range of values. 36Cl- distribution provided an accurate measurement of plasma membrane potential between -4 and -40 mV. At higher potentials intracellular chloride concentration is less than 20% of the extracellular concentration and errors due to uncertainties in the measurement of intracellular volume and of the contamination of cell pellets by extracellular medium precluded accurate determination of membrane potential: thus in our experiments 36Cl- underestimated the plasma membrane potential at -68 mV by 8 mV.

Proton leak and control of oxidative phosphorylation in perfused, resting rat skeletal muscle.

The distribution of control over the resting respiration rate (and other variables) was assessed in perfused rat skeletal muscle. The results indicate that the general pattern of control in resting muscle is similar to that seen in isolated rat liver cells (Brown et al. (1990) Biochem. J. 192, 355-362). Control over resting mitochondrial oxygen consumption was distributed between reactions involved in substrate oxidation (flux control coefficient = 0.44 +/- 0.28) and those involved in ATP turnover (0.21 +/- 0.09). The mitochondrial proton leak also had an important share of the control (0.38 +/- 0.21). Since proton leak also has significant control over the resting respiration rate of isolated liver cells and liver and skeletal muscle account for around 60% of the standard metabolic rate of a rat, then these results indicate the potential importance of proton leak as a mechanism of regulating metabolic rate.

On the nature of the mitochondrial proton leak.

Respiring mitochondria have a significant passive permeability to protons; the mechanism of this proton leak is unknown. Several putative mechanisms were tested. Mitochondrial permeability to small sugars was unaffected by energization, suggesting that there is no significant dielectric breakdown at high membrane potential. Mitochondria are argued to have a proton permeability that is 6 to 8 orders of magnitude higher than the permeability to other cations, suggesting that the proton leak is probably not via a simple pore or membrane defect. 15-30% of the proton leak of freshly prepared mitochondria was extractable with bovine serum albumin and is probably due to fatty acids. Little if any of the proton leak appears to be due to cycling of ions other than protons, or to be associated with the functional activity of the proton pumps. The mitochondrial proton leak shares several properties with the proton permeability of pure phospholipid bilayers, suggesting that they share the same mechanism, although the leak through the bilayer in mitochondria may be modified by the presence of proteins.

Control analysis of systems with reaction blocks that 'cross-talk'.

Practical application of metabolic control analysis has been facilitated by use of the top-down approach, which divides a metabolic system into a small number of reaction blocks, linked by a few key intermediates. Previous papers have stressed that communication between blocks should be only through the explicit intermediates, 'cross-talk' between reaction blocks invalidated the approach. Here we show how the restriction is a result of the use of inhibitors of the blocks, and can be overcome if other system modulations are used. We also show a way to treat the related problem of enzymes that appear in more than one block such as the analysis of glycolytic substrate cycles into ATP consuming and net flux activities.

The mechanism of Ca2+ stimulation of citrulline and N-acetylglutamate synthesis by mitochondria.

ATP-driven citrulline synthesis by mitochondria treated with oligomycin, uncoupler and Ca2+ ionophore is stimulated more than 2-fold by an increase in extramitochondrial free [Ca2+] in the range 1-5 microM. Stimulation increases with the length of preincubation of mitochondria with Ca2+. EGTA prevents stimulation if added at the start of the preincubation period, but is without effect if added at the end, suggesting that Ca2+ acts indirectly on citrulline synthesis via the accumulation of an intermediate. Neither carbamoyl-phosphate synthase (ammonia) nor ornithine carbamoyltransferase are stimulated by up to 50 microM free Ca2+ in mitochondrial extracts, but N-acetylglutamate synthase is stimulated about 30% by 10 microM free Ca2+. We propose that an increase in the activity of N-acetylglutamate synthase in response to an increase in free [Ca2+] in the mitochondrial matrix may contribute to hormonal stimulation of the urea cycle.

Proportional activation coefficients during stimulation of oxidative phosphorylation by lactate and pyruvate or by vasopressin.

A 'proportional activation' approach designed to deal with the influence of external effectors within biochemical systems is described. The proportional activation coefficient, which enables the quantitative determination of the relative stimulation of different parts of a system by a given effector, is defined. The proportional activation approach was used to calculate the relative activation of delta p-producing and delta p-consuming subsystems during stimulation of the respiration rate of cells by a variety of different effectors. Oxidative phosphorylation was stimulated by the addition of either lactate and pyruvate (10 mM and 1 mM) or vasopressin. The addition of lactate and pyruvate to suspensions of resting hepatocytes increased the respiration rate by about 50%. The delta p-consuming subsystem was stimulated about 60% as much as the delta p-producing subsystem. Quinolinic acid, commonly considered to be a specific inhibitor of gluconeogenesis, was found to block the delta p-producing oxidative subsystem as well as the delta p-consuming subsystem, indicating some nonspecific effects of this inhibitor. Addition of vasopressin to hepatocytes that were incubated in the presence of lactate and pyruvate resulted in an increase of the respiratory rate by up to 35%. The relative stimulation of the delta p-producing and delta p-consuming subsystems was essentially equal. Using the 'proportional activation approach' to analyse these and previously published data, it is shown that substrates (lactate/pyruvate and fatty acids), Ca(2+)-acting hormones (vasopressin and others) and calcium in muscles (heart muscle and skeletal muscle) activate both subsystems to a similar extent (it concerns especially Ca(2+)-dependent systems).

Effects of the mitogen concanavalin A on pathways of thymocyte energy metabolism.

The lectin concanavalin A (Con A) acts as a mitogen that preferentially activates T-cells. It stimulates the energy metabolism of thymocytes within seconds of exposure. We studied short-term effects (<30 min) of Con A on a conceptually simplified model system of rat thymocyte energy metabolism in the concentration range of 0-2 microg Con A per 107 cells, using metabolic control analysis. The model system consisted of three blocks of reactions, linked by the common intermediate mitochondrial membrane potential (Delta[psi]m): the substrate oxidation reactions, which produce the linking intermediate, and the proton conductance (or leak) and ATP turnover pathways which consume Delta[psi]m. Firstly, we used top-down elasticity analysis to establish which subsystems are targeted by Con A. Secondly, we quantitatively analysed the steady-state regulation of the system variables by Con A: how do the subsystem fluxes respond to Con A individually and as a whole? Our results indicate that: (1) steady-state respiration and Delta[psi]m increase as Con A concentration is raised, but at higher concentrations the increase in respiration is less and Delta[psi]m falls; (2) Con A independently changes the kinetics of the reactions that produce and consume Delta[psi]m: the Delta[psi]m-producing reactions are inhibited, and the reactions involved in ATP turnover are stimulated; and (3) the overall effects of Con A are mostly mediated by effects on ATP turnover.

The contribution of ATP turnover by the Na+/K+-ATPase to the rate of respiration of hepatocytes. Effects of thyroid status and fatty acids.

In less than 1 min ouabain maximally inhibits oxygen consumption due to gramicidin-induced ATP turnover by the Na+/K+-ATPase in hepatocytes. Ouabain rapidly inhibits respiration on palmitate or glucose by only 6-10% indicating that the Na+/K+-ATPase plays a minor role in cell ATP turnover. 29% of the extra oxygen consumption of hepatocytes isolated from hyperthyroid rats was inhibited by ouabain showing that the Na+/K+-ATPase is responsible for some but not the majority of the stimulation of respiration induced by thyroid hormone.

The proton permeability of liposomes made from mitochondrial inner membrane phospholipids: no effect of fatty acid composition.

The proton permeability of the mitochondrial inner membrane has been shown to correlate with the fatty acid composition of its phospholipids. In this paper, we test the hypothesis that the proton permeability of the phospholipid bilayer portion of the membrane depends on phospholipid fatty acid composition. We measured the proton permeability of liposomes made from the mitochondrial inner membrane phospholipids of eight vertebrates, representing a ten-fold range of mitochondrial proton leak and a three fold range of unsaturation index. At a membrane potential (delta psi) of 160 mV at 37 degrees C, the liposomes all had the same proton leak rate, about 30 nmol protons min-1 mg-1 phospholipid. There was no correlation between liposome proton permeability and phospholipid fatty acid composition.

A top-down control analysis in isolated rat liver mitochondria: can the 3-hydroxy-3-methylglutaryl-CoA pathway be rate-controlling for ketogenesis?

We incubated isolated liver mitochondria with palmitoyl-CoA, 2,4-dinitrophenol and malonate. Under these conditions all the flux of carbon from palmitoyl-CoA was directed towards acetoacetate synthesis. We measured the rate of acetyl-CoA formation from palmitoyl-CoA (by measuring the rate of oxygen consumption) and the rate of acetoacetate production from acetyl-CoA at three different acetyl-CoA/CoA ratios. Using the top-down approach of metabolic control analysis we calculated the control over ketogenesis exerted by (a) the conversion of extramitochondrial palmitoyl-CoA to intramitochondrial acetyl-CoA and by (b) the conversion of acetyl-CoA to acetoacetate (the 'HMG-CoA pathway'). The overall flux control coefficients of the groups of enzymes involved in (a) and (b) over ketogenesis were 0.28 and 0.72, respectively. Our results show that it is possible for significant control to be exerted over ketogenesis by the enzymes of the HMG-CoA pathway.

Characterization of betaine efflux from rat liver mitochondria.

In order to investigate the control of endogenous betaine supply to the cytoplasmic enzyme betaine-homocysteine methyltransferase, it was necessary to understand how betaine synthesized within the mitochondrial matrix is transported across the mitochondrial inner membrane. Mitochondria were loaded with radiolabelled betaine and efflux was measured in a medium at physiological ionic strength. Efflux of radiolabelled betaine occurred continuously with time. The efflux rate was unaffected by the presence or absence of a source of energy except at high membrane potentials, where betaine efflux rate increased 2-3-fold. Titration of the membrane potential demonstrated a non-ohmic relationship between betaine efflux rate and membrane potential. The rate of betaine efflux was proportional to the matrix betaine concentration up to 9 mM. Efflux was unaffected by addition of analogues of betaine and known mitochondrial transport inhibitors. N-Ethylmaleimide did inhibit efflux by 50%, but evidence suggested that the effect was non-specific. The lack of saturability or other evidence for a transport system suggests that betaine escapes from mitochondria by simple diffusion. The relative diffusion rates of glycine, sarcosine, dimethylglycine and betaine suggest that increasing the degree of N-methylation lowers diffusion rate.

Characteristics of mitochondrial proton leak and control of oxidative phosphorylation in the major oxygen-consuming tissues of the rat.

Maintenance of an electrochemical proton gradient across the mitochondrial inner membrane against the significant proton permeability of the membrane accounts for 25-30% of resting oxygen consumption in hepatocytes. It has been proposed that proton leak could be a significant contributor to resting metabolic rate in mammals if it were present in other tissues. Mitochondria were isolated from the major oxygen-consuming tissues (liver, kidney, brain and skeletal muscle) of the rat. In each tissue, the mitochondria showed significant proton leak with the same characteristic non-linear dependence on membrane potential. Liver and kidney mitochondria showed similar membrane proton permeability per mg of mitochondrial protein; brain and muscle permeabilities were greater when expressed in this way. Differences in the kinetic response of the substrate oxidation and phosphorylating systems to membrane potential were observed. The substrate oxidation system was more active in kidney, brain and skeletal muscle mitochondria than in liver mitochondria per mg of mitochondrial protein. Liver and kidney phosphorylating systems were less active than brain and skeletal muscle per mg of mitochondrial protein. The control of oxidative phosphorylation was also assessed. The distribution of control in mitochondria isolated from the four tissue types was found to be similar.

Control and kinetic analysis of ischemia-damaged heart mitochondria: which parts of the oxidative phosphorylation system are affected by ischemia?

We investigated the effects of ischemia on the kinetics and control of mitochondria isolated from normal and ischemic heart. The dependence of the respiratory chain, phosphorylation system and proton leak on the mitochondrial membrane potential were measured in mitochondria from hearts after 0, 30 min and 45 min of in vitro ischemia. Data showed that during the development of ischemia from the reversible (30 min) to the irreversible (45 min) phase, a progressive decrease in activity of the respiratory chain occurs. At the same time an increase in proton leak across the mitochondrial inner membrane was observed. Phosphorylation is inhibited but seems to be less affected by ischemia than respiratory chain or proton leak. Control coefficients of the 3 blocks of reactions over respiration rate were determined in different respiratory states between state 4 and state 3. Ischemia caused the control exerted by the proton leak to increase in state 3 and the intermediate state and caused the control by the phosphorylation system to decrease in the intermediate state. Taken together, these results indicate that the main effects of ischemia on mitochondrial respiration are an inhibition of the respiratory chain and an increase of the proton leak.

Calcium regulation of oxidative phosphorylation in rat skeletal muscle mitochondria.

Activation of oxidative phosphorylation by physiological levels of calcium in mitochondria from rat skeletal muscle was analysed using top-down elasticity and regulation analysis. Oxidative phosphorylation was conceptually divided into three subsystems (substrate oxidation, proton leak and phosphorylation) connected by the membrane potential or the protonmotive force. Calcium directly activated the phosphorylation subsystem and (with sub-saturating 2-oxoglutarate) the substrate oxidation subsystem but had no effect on the proton leak kinetics. The response of mitochondria respiring on 2-oxoglutarate at two physiological concentrations of free calcium was quantified using control and regulation analysis. The partial integrated response coefficients showed that direct stimulation of substrate oxidation contributed 86% of the effect of calcium on state 3 oxygen consumption, and direct activation of the phosphorylation reactions caused 37% of the increase in phosphorylation flux. Calcium directly activated phosphorylation more strongly than substrate oxidation (78% compared to 45%) to achieve homeostasis of mitochondrial membrane potential during large increases in flux.

Uncoupling protein 2 from carp and zebrafish, ectothermic vertebrates.

Uncoupling protein 1 (UCP1) is of demonstrated importance in mammalian thermogenesis, and early hypotheses regarding the functions of the newly discovered UCP homologues, UCP2, UCP3 and others, have focused largely on their potential roles in thermogenesis. Here we report the amino acid sequences of two new UCPs from ectothermic vertebrates. UCPs from two fish species, the zebrafish (Danio rerio) and carp (Cyprinus carpio), were identified in expressed sequence tag databases at the European Molecular Biology Laboratory. cDNAs from a C. carpio 'peritoneal exudate cell' cDNA library and from a D. rerio 'day 0 fin regeneration' cDNA library were obtained and fully sequenced. Each cDNA encodes a 310 amino acid protein with an average 82% sequence identity to mammalian UCP2s. The fish UCP2s are about 70% identical to mammalian UCP3s, and 60% identical to mammalian UCP1s. Carp and zebrafish are ectotherms--they do not raise their body temperatures above ambient by producing excess heat. The presence of UCP2 in these fish thus suggests the protein may have function(s) not related to thermogenesis.