Changes in energy metabolism due to anthelmintics in Fasciola hepatica maintained in vitro

The effects of rafoxanide (RFX), nitroscanate (NSC) and mebendazole (MBZ) on oxidative pathways in whole F. hepatica maintained in a simple salt solution have been examined. The anthelmintics did not alter glucose uptake or glycogen mobilization. NSC and RFX depressed ATP and increased AMP levels. MBZ behaved similarly at first, but later depressed the total adenine nucleotides. All three drugs influenced end product formation, increasing it initially, although by different mechanisms. With NSC, early increases in lactate and acetate excretion were later abolished. With RFX, there was an initial increased production of acetate and propionate. Later, excretion of propionate was reduced and that of succinate was increased. MBZ also increased succinate excretion, but to a much greater extent. In addition, it inhibited lactate production. A number of effects of the drugs on the internal concentrations of metabolic intermediates are described. The mechanisms of action of the drugs are discussed.     

The metabolic integrity of Fasciola hepatica during in vitro maintenance

Levels of metabolic intermediates and end products in F. hepatica after 24 and 48 h in Hédon-Fleig salt solution with added glucose were compared with levels obtained immediately on removal from the host. Glycogen levels dropped initially, probably due to the expulsion of eggs; thereafter they remained constant. Internal glucose concentrations increased as the parasites equilibrated with the medium. Other changes in internal pool sizes were consistent with regulation to the in vitro conditions. ATP levels increased; ATP/ADP ratios were maintained. Comparisons of mass action ratios and equilibrium constants suggest that hexokinase, pyruvate kinase and phosphofructokinase are regulatory. Output of excretory products approached linearity; from the calculated regressions the proportions of lactate, acetate and propionate were 1: 2: 4. The implications for metabolic regulation in F. hepatica are briefly discussed, and it is concluded that, for at least 48 h in vitro, energy metabolism is not adversely affected.     

Regulation of glycolysis by adenosine diphosphate in Pisum sativum

The role of ADP in controlling glycolysis has been examined in a soluble extract of germinating pea seeds. A shortage of ADP appears to retard glycolysis principally by restricting the conversion of phosphopyruvate to pyruvate rather than by restricting formation of phosphoglycerate. Upon addition of ADP to the extract there is an immediate decrease in the concentration of phosphopyruvate accompanied by an increase in pyruvate. Apparently the pyruvate-kinase step shows the most marked response to fluctuations in ADP availability. The glycolytic response to ADP depends on the concentration of ATP magnesium ions. The relation of magnesium-ion availability to adenine-nucleotide control of glycolysis is discussed.     

Detection of a quaternary organization into dimer of trimers of Corynebacterium ammoniagenes FAD synthetase at the single-molecule level and at the in cell level

Biochemical characterization of Corynebacterium ammoniagenes FADS (CaFADS) pointed to certain confusion about the stoichiometry of this bifunctional enzyme involved in the production of FMN and FAD in prokaryotes. Resolution of its crystal structure suggested that it might produce a hexameric ensemble formed by a dimer of trimers. We used atomic force microscopy (AFM) to direct imaging single CaFADS molecules bound to mica surfaces, while preserving their catalytic properties. AFM allowed solving individual CaFADS monomers, for which it was even possible to distinguish their sub-molecular individual N- and C-terminal modules in the elongated enzyme. Differences between monomers and higher stoichiometries were easily imaged, enabling us to detect formation of oligomeric species induced by ligand binding. The presence of ATP:Mg^2 + particularly induced the appearance of the hexameric assembly whose mean molecular volume resembles the crystallographic dimer of trimers. Finally, the AFM results are confirmed in cross-linking solution, and the presence of such oligomeric CaFADS species detected in cell extracts. All these results are consistent with the formation of a dimer of trimers during the enzyme catalytic cycle that might bear biological relevance.     

Anisakis simplex: CO(2)-fixing enzymes and development throughout the in vitro cultivation from third larval stage to adult

We studied the effect of CO(2) on the in vitro cultivation of Anisakis simplex, an aquatic parasitic nematode of cetaceans (final hosts) and fish, squid, crustaceans and other invertebrates (intermediate/paratenic hosts), and, occasionally, of man (accidental host). The results showed that a high pCO(2), at a suitable temperature, is vital for the optimum development of these nematodes, at least from the third larval stage (L3) to adult. After 30 days cultivation in air, molting to L4 (fourth larval stage) was reduced to 1/3, while survival was about 1/3 of that when cultivated in air + 5% CO(2). The activity of the CO(2)-fixing enzymes, PEPCK and PEPC, was also studied. Throughout the development of the worms studied, PEPCK activity was much higher than that of PEPC (e.g., 305 vs. 6.8 nmol/min.mg protein, respectively, in L3 collected from the host fish). The activity of these enzymes in the worms cultivated in air + 5% CO(2) was highest during M3, and was also generally higher than that of those cultivated in air only, especially during molting from L3 to L4 (e.g., in recently molted L4, PEPCK activity was 3.7 times greater than that of PEPC 2.9 times greater than when cultivated in air).     

A path analysis of the causal relationships between red cell glycolytic intermediates, ADP and ATP in sickle cell anemia

The statistical relationships among the glycolytic intermediates (GI)) of the Embden-Meyerhof pathway, adenine nucleotides (ANs) and various hematological measures were estimated for 34 sickle cell anemia patients. Heterogeneity in linear and quadratic regressions of hemoglobin and hematocrit, both singly and jointly, on the GI and AN variables implied 1) that any single formula to standardize optical density measures of the GIs and ANs on a per gram hemoglobin or per liter cell water basis would not uniformly remove hemoglobin and hematocrit effects: 2) that ignoring significant hematological effects could bias the estimates of correlation among GIs and ANs; and 3) that hemoglobin and hematocrit measures do not reflect the same source of variability. The correlations among the GIs and ANs, after adjustment for hematological variability, were analyzed by path analysis to determine which of five proposed path models for cause and effect relationships were compatible with the data. AMP had a greater influence on ADP (coefficient of determination (CD) = 23%) than all the GIs together, while G6P and ADP influenced ATP variability the most (CD = 33% and 12%). The contributions of unknown factors to ADP and ATP variability were large for all models (CD = 56--77%) possibly due to stress of sickle cell disease. The path model with AMP and the four GIs (G6P, F6P, FDP, DHAP) influencing ADP variation, and the same GIs and ADP influencing ATP was the model most compatible with the data.     

The effect of lead ions on the energy metabolism of human erythrocytes in vitro

The aim of this work was to evaluate the influence of chronic exposure to lead ions on the parameters of energetic status of human erythrocytes in vitro. Umbilical cord erythrocytes were incubated with lead acetate at final lead ion concentrations ranging from 10 to 200 microg/dl. ATP, ADP, AMP, adenosine, GTP, GDP, GMP, guanosine, IMP, inosine, hypoxanthine, NAD and NADP concentrations in erythrocytes were determined using HPLC. Scanning electron micrographs of erythrocytes were taken. The mean concentrations of ATP, GTP, NAD and NADP, and mean values of adenylate energy charge (AEC) and GEC in cells incubated at the presence of lead ions were significantly lower after 20 h of incubation. Concentrations of purine degradation products (Ado, Guo, Ino) and Hyp were significantly higher. It is suggested that lead ions affect the energy metabolism of erythrocytes. Morphological changes in erythrocytes correspond to the increase of lead ions in the incubation mixture and to the decrease of ATP concentration in erythrocytes. A decrease in NAD and ATP concentration in erythrocytes could be a sensitive indicator of energy process disturbance, useful in monitoring in case of chronic lead exposure.     

Energetics of photosynthesis in Zea mays. II. Studies of the flash-induced electrochromic shift and fluorescence induction in mesophyll chloroplasts

Patterns of electron transfer in isolated mesophyll chloroplasts of maize (Zea mays L.) were studied in the presence of the physiological substrates, oxaloacetate, 3-phosphoglycerate and pyruvate. Flash-induced absorbance changes due to the electrochromic pigment band-shift (P-518) were used to estimate relative electron flow rates through the cyclic and non-cyclic pathways of electron transport. Further information on the redox state of electron carriers and the activity of coupled electron flow was obtained from measurements of fluorescence induction and of actinic-light-induced fluorescence changes. The results demonstrate the importance of correct redox poising for optimal rates of photosynthesis and are discussed in relation to the operation and regulation of photosynthesis in the C₄ system.     

Evidence of oxidative stress and mitochondrial respiratory chain dysfunction in an in vitro model of sepsis-induced kidney injury

To investigate the role of oxidative stress and/or mitochondrial impairment in the occurrence of acute kidney injury (AKI) during sepsis, we developed a sepsis-induced in vitro model using proximal tubular epithelial cells exposed to a bacterial endotoxin (lipopolysaccharide, LPS). This investigation has provided key features on the relationship between oxidative stress and mitochondrial respiratory chain activity defects.     

Myosin regulatory domain orientation in skeletal muscle fibers: application of novel electron paramagnetic resonance spectral decomposition and molecular modeling methods

Reorientation of the regulatory domain of the myosin head is a feature of all current models of force generation in muscle. We have determined the orientation of the myosin regulatory light chain (RLC) using a spin-label bound rigidly and stereospecifically to the single Cys-154 of a mutant skeletal isoform. Labeled RLC was reconstituted into skeletal muscle fibers using a modified method that results in near-stoichiometric levels of RLC and fully functional muscle. Complex electron paramagnetic resonance spectra obtained in rigor necessitated the development of a novel decomposition technique. The strength of this method is that no specific model for a complex orientational distribution was presumed. The global analysis of a series of spectra, from fibers tilted with respect to the magnetic field, revealed two populations: one well-ordered (+/-15 degrees ) with the spin-label z axis parallel to actin, and a second population with a large distribution (+/-60 degrees ). A lack of order in relaxed or nonoverlap fibers demonstrated that regulatory domain ordering was defined by interaction with actin rather than the thick filament surface. No order was observed in the regulatory domain during isometric contraction, consistent with the substantial reorientation that occurs during force generation. For the first time, spin-label orientation has been interpreted in terms of the orientation of a labeled domain. A Monte Carlo conformational search technique was used to determine the orientation of the spin-label with respect to the protein. This in turn allows determination of the absolute orientation of the regulatory domain with respect to the actin axis. The comparison with the electron microscopy reconstructions verified the accuracy of the method; the electron paramagnetic resonance determined that axial orientation was within 10 degrees of the electron microscopy model.     

Effects of precipitation on photosynthesis and water potential in Andropogon gerardii and Schizachyrium scoparium in a southern mixed grass prairie

In grassland ecosystems, spatial and temporal variability in precipitation is a key driver of species distributions and population dynamics. We experimentally manipulated precipitation to understand the physiological basis for differences in responses of species to water availability in a southern mixed grass prairie. We focused on the performance of two dominant C₄ grasses, Andropogon gerardii Vitman and Schizachyrium scoparium (Michx.) Nash, in treatments that received ambient rainfall, half of ambient rainfall (“drought” treatment), or approximately double ambient rainfall (“irrigated” treatment). Water potentials of S. scoparium were lower than A. gerardii, suggesting superior ability to adjust to water deficit in S. scoparium. Additionally, drought reduced photosynthesis to a greater extent in A. gerardii compared to S. scoparium. Leaf-level photosynthesis rates were similar in ambient and irrigated treatments, but were significantly lower in the drought treatment. Although stomatal conductance was reduced by drought, this was not limiting for photosynthesis. Leaf δ¹³C values were decreased by drought, caused by an increase in C_i/C_a. Chlorophyll fluorescence measures indicated light-harvesting rates were highest in irrigated treatments, and were lower in ambient and drought treatments. Moreover, drought resulted in a greater proportion of absorbed photon energy being lost via thermal pathways. Reductions in photosynthesis came as a result of non-stomatal limitations in the C₄ cycle. Our results provide mechanistic support for the hypothesis that S. scoparium is more drought tolerant than A. gerardii.     

In the early phase of programmed cell death in Tobacco Bright Yellow 2 cells the mitochondrial adenine nucleotide translocator, adenylate kinase and nucleoside diphosphate kinase are impaired in a reactive oxygen species-dependent manner

To investigate whether and how mitochondria can change in plant programmed cell death (PCD), we used the non-photosynthetic Tobacco Bright Yellow 2 (TBY-2) cells. These can be synchronized to high levels, stand out in terms of growth rate and homogeneity and undergo PCD as a result of heat shock. Using these cells we investigated the activity of certain mitochondrial proteins that have a role in providing ATP and/or other nucleoside triphosphates (NTPs). We show that, already after 2 h from the heat shock, when cell viability remains unaffected, the rate of ADP/ATP exchange due to adenine nucleotide translocator (ANT) activity, and the rate of the reactions catalysed by adenylate kinase (ADK; EC 2.7.4.3) and nucleoside diphosphate kinase (NDPK; EC 2.7.4.6) are inhibited in a non-competitive-like manner. In all cases, externally added ascorbate partially prevented the inhibition. These effects occurred in spite of minor (for ANT) or no changes in the mitochondrial protein levels as immunologically investigated. Interestingly, a decrease of both the steady state level of the ascorbate pool and of the activity of l-galactono-γ-lactone dehydrogenase (GLDH) (EC 1.3.2.3), the mitochondrial enzyme catalysing the last step of ascorbate biosynthesis, were also found.     

The chlorophyll a fluorescence induction pattern in chloroplasts upon repetitive single turnover excitations: Accumulation and function of QB-nonreducing centers

The increase of chlorophyll fluorescence yield in chloroplasts in a 12.5 Hz train of saturating single turnover flashes and the kinetics of fluorescence yield decay after the last flash have been analyzed. The approximate twofold increase in F_m relative to F_o, reached after 30-40 flashes, is associated with a proportional change in the slow (1-20 s) component of the multiphasic decay. This component reflects the accumulation of a sizeable fraction of Q_B-nonreducing centers. It is hypothesized that the generation of these centers occurs in association with proton transport across the thylakoid membrane. The data are quantitatively consistent with a model in which the fluorescence quenching of Q_B-nonreducing centers is reversibly released after second excitation and electron trapping on the acceptor side of Photosystem II.     

The response of oscillating glycolysis to perturbations in the NADH/NAD system: a comparison between experiments and a computer model.

The glycolytic pathway is described by a set of coupled non linear differential equations of first order with respect to time. The individual terms of these equations consist of enzyme velocities assuming a steady state hypothesis for the enzymatic forms. These are specified and the system is solved numerically. Oscillations are explained by interaction of PFK with the adenylate system. The conditions for the occurrence of oscillations are tested in a series of computer runs. The phase relations between intermediates of the model agree with those found in yeast cells. As an application of the model the disturbation of oscillations by the addition of acetaldehyde is simulated. The predictions of the model agree with experimental results.