Structural basis of cation exchange, complex formation and redox properties in chloragosomes.

Components of chloragosomes isolated from Octolasium transpadanum ROSA were separated by fractional extraction. The chemical composition of the fractions was determined and their effect on the anion- and cation-binding capability and on the lipophilic property of chloragosomes was studied. The acid-alcoholic extract of chloragosomes contained, among others, metalloporphyrins with 2 or 4 free -COOH groups; the residuum consisted of basic proteins. The metalloporphyrins and phosphatides gained by extraction with chloroform-methanol neutralize the basic groups of the chloragosome proteins, thus, an excess of free acidic groups develops, which is responsible for the polyanionic nature and cation exchange of chloragosomes. The apolar groups of phosphatides and carotenoids are responsible for the lipophilic nature of chloragosomes. Under experimental circumstances both in vivo and in vitro, organic cations were bound to chloragosomes, partially by a cation-exchange mechanism and partially by formation of more stable complexes. A small amount of anions may be absorbed by the bound cations. The diluted acidic extract of chloragosomes predominantly contain organic cations, in the present study riboflavin, flavin nucle0tide and thiamine were determined. Chloragosomes, owing to their structure, form complexes of varying stability with anions, cations and hydrophilic compounds equally. This feature explains their capability of cumulating trophic and toxic substances, while their redox activity is explained by their metalloporphyrin, flavin, thiamine and carotene content.     

In vivo cumulation and discharge of azine, thiazine and xanthene dyes and their effects on the chloragogen cells of Lumbricidae (Oligochaeta)

The in vivo cumulation of neutral red, methylene blue and acriflavine in the body wall, midgut epithelium and chloragosomes of Lumbricus terrestris L. and Octolasium transpadanum Rosa, and the discharge of these dyes by chloragosomes was investigated by spectrophotometry. The chloragosomes cumulated the largest amount of the ingested dyes. Electron microscopy displayed the activation of the chloragogen cells and an increased chloragosome formation on the first days of dye intake. In dye-free environment, the dye content of the chloragosomes decreased rapidly. The above properties of the chloragogen cells indicate the role of these cells in the defence mechanism against the toxic effect of certain cationic xenobiotics ingested via the intestinal tract.     

Uptake and long-time storage of natural and synthetic dyes by earthworm chloragocytes. In vivo and in vitro investigations

Cationic or anionic dyes adsorbed onto cellulose granulate were transported across the gut wall, bound to blood proteins, and accumulated by the chloragocytes. Solubility in water promoted accumulation. The dyes ended up mainly in the chloragosomes. Down to 20 μmol dye per litre soil water resulted in visible accumulation. Worms which after dye-exposure were kept dye-free for 5 months retained substantial amounts of dye in the chloragosomes. In vitro experiments indicate that the binding to chloragosomes of synthetic and natural phenolics is by ion exchange with calcium phosphate and with an uncharacterized matrix-bound calcium chelator, aided by hydrophobic interactions between the dye and constituents of the chloragosome matrix. The findings are relevant for the evaluation of the effects of constant or periodic soil contamination with industrial or agricultural organochemicals.     

Transformation of p-nitrochlorobenzene by Escherichia coli

Microorganisms that have not been adapted to p-nitrochlorobenzene (p-NCB) are capable of transforming this compound. Washed cell of Escherichia coli, the resting culture and the homogenate of disintegrated cells transform p-NCB into p-chloroaniline (p-CA). The growing culture of E. coli (Eh = -210 mV) reduces the nitro group of p-NCB. If E. coli cells are separated from the cultural broth under strictly anaerobic conditions, the redox potential rises abruptly (Eh = -110 mV); the filtrate does not transform p-NCB into p-Ca. The rate at which E. coli reduces the nitro group of p-NCB depends on the redox potential of the medium. It is likely that any microorganism is capable of reducing p-NCB at a low value of the redox potential.     

Effects of Cyanide Ion and Hypoxia on the Volumes of Second-Stage Juveniles of Meloidogyne incognita in Polyethylene Glycol Solutions

Changes in the volumes of second-stage juveniles of Meloidogyne incognita were monitored in aqueous solutions of polyethylene glycol supplemented with dilute balanced salts. At key points within a 48-hour cycle of fluctuating water potential, nematodes were placed under hypoxic conditions or exposed to the respiratory inhibitor, sodium cyanide, to detect any respiration-dependent process that regulates volume. Aerobic respiratory arrest at -500 kPa induced pronounced water loss, lateral and dorsoventral collapse of the body wall, and abnormal failure to shorten longitudinally. Durations of hypoxia that were innocuous in dilute solutions were lethal during 500 kPa increases and decreases in water potential; the same water potential changes under aerobic conditions had no effect on viability. Data are consistent with the hypothesis that respiration is essential to survive water potential changes.     

Oxidation-reduction potential of the ferro-ferricyanide system in buffer solutions

The redox potential (E₀′) of the potassium ferrocyanide-potassium ferricyanide oxidation-reduction potential buffer was measured in four pH buffer solutions, acetate, Tris, phosphate, and borate, under specified conditions of pH, solution composition, and temperature. The potentials reported should be accurate, on the hydrogen electrode scale, to within about 2 mV and precise to within at least ±0.3 mV. Although the potential of the ferro-ferricyanide couple is sensitive to fairly small changes in experimental conditions, several methods are discussed by which this potential can be estimated with a reasonable degree of accuracy (about 2–10 mV) in solutions which differ somewhat from the particular solutions reported here. Attention is called to the need for greater care in specifying experimental conditions in the determination of redox potentials of various biological species.     

Zinc sequestration by earthworm (Annelida: Oligochaeta) chloragocytes. An in vivo investigation using fully quantitative electron probe X-ray micro-analysis

The elemental compositions of chloragosome "granules" in the earthworm Lumbricus rubellus living in non-polluted and heavily Zn-polluted soils were determined by fully quantitative electron probe X-ray microanalysis. P, Ca, S and Zn were the major elemental components of the chloragosomes. The in vivo accumulation of Zn by the chloragosomes was accompanied by diminished chloragosomal Ca concentrations. Zn was apparently bound by at least two ligand pools (Pool 1 = uncharacterised; Pool 2 = P-containing ligands, binding approximately 45% and 55% of the Zn, respectively) in the "control" chloragosomes. In Zn-contaminated chloragosomes, most (approximately 70%) was bound by P-containing ligand(s) but some (less than 1%) was also bound by S-containing ligands. It is suggested that the sequestration of Zn in chloragosomes results in the detoxification of the metal by accumulative immobilisation.     

Carotenoids as antioxidants: spin trapping EPR and optical study.

The role of several natural and synthetic carotenoids as scavengers of free radicals was studied in homogeneous solutions. A set of free radicals: *OH, *OOH, and *CH(3) were generated by using the Fenton reaction in dimethyl sulfoxide. It was shown that the spin trapping technique is more informative than optical methods for the experimental conditions under study. 5,5-Dimethyl-pyrroline-N-oxide (DMPO) and N-tert-butyl-alpha-phenylnitrone (PBN) were used as spin traps for the EPR studies. The results show that the scavenging ability of the carotenoids towards radical *OOH correlates with their redox properties.     

Cold-stress induced formation of calcium and phosphorous rich chloragocyte granules (chloragosomes) in the earthworm Eisenia fetida

The cytochemical and functional characteristics of chloragocytes of both 'control' and cold-stressed Eisenia fetida were examined. Flow cytometry revealed the heterogeneity of chloragocytes: the first group was characterized by low, the second one by high acid phosphatase (AcP) content. In 'control' animals the former, in cold-stressed ones the latter type were the dominant form. The elevated AcP-activity correlated with the accumulation of autophagic vacuoles (AVs) in chloragocytes. Both AVs and all small chloragosomes showed high AcP activity, while most of the large chloragosomes did not display any. Most 'control' granules (0.75-1.25 μm) contained high amounts of Ca and P, with less and variable quantities of S, Cl, K, Fe and Zn. Small chloragosomes with low Ca and P concentrations were seldom found. In cold-stressed animals the number of small granules (0.25-0.75 μm) increased up to 40% of total population. Their Ca and P contents were significantly lower; S and Fe concentrations were higher than those of large chloragosomes (1.0-1.5 μm). Our results prove that the formation and elemental composition of chloragosomes can be influenced by environmental stressors and suggest that the mature chloragosomes are tertiary lysosomes and their formation is coupled to autophagocytosis.     

Control of reversible intracellular transfer of reducing potential.

Isolated rat liver mitochondria were incubated in the presence of a reconstituted malate-aspartate shuttle under carboxylating conditions in the presence of glutamate, octanoyl-carnitine and pyruvate, or a preset lactate/pyruvate ratio. The respiration and attendant energy state were varied with soluble F1-ATPase. Under these conditions reducing equivalents are exported due to pyruvate carboxylation. This was shown by lactate production from pyruvate and by a substantial increase in the lactate/pyruvate ratio. This led to a competition between malate export and energy-driven malate cycling via the malate-aspartate shuttle, resulting in a lowered redox segregation of the NAD systems between the mitochondrial and extramitochondrial spaces. If pyruvate carboxylation was blocked, this egress of reducing equivalents was also blocked, leading to an elevated value of redox segregation, delta G(redox) (in kJ) = -5.7 log(NAD+/NADHout)/(NAD+/NADHin) being then equal to approximately one-half of the membrane potential, in accordance with electrogenic glutamate/aspartate exchange. Reconstitution of malate-pyruvate cycling led to a further kinetic decrease in the original malate-aspartate shuttle-driven value of delta G(redox). Therefore, the value of segregation of reducing potential between mitochondria and cytosol caused by glutamate/aspartate exchange can be diminished kinetically by processes exporting reducing equivalents from mitochondria, such as pyruvate carboxylation and pyruvate cycling.     

Microbial communities acclimate to recurring changes in soil redox potential status

Rapidly fluctuating environmental conditions can significantly stress organisms, particularly when fluctuations cross thresholds of normal physiological tolerance. Redox potential fluctuations are common in humid tropical soils, and microbial community acclimation or avoidance strategies for survival will in turn shape microbial community diversity and biogeochemistry. To assess the extent to which indigenous bacterial and archaeal communities are adapted to changing in redox potential, soils were incubated under static anoxic, static oxic or fluctuating redox potential conditions, and the standing (DNA‐based) and active (RNA‐based) communities and biogeochemistry were determined. Fluctuating redox potential conditions permitted simultaneous CO₂ respiration, methanogenesis, N₂O production and iron reduction. Exposure to static anaerobic conditions significantly changed community composition, while 4‐day redox potential fluctuations did not. Using RNA : DNA ratios as a measure of activity, 285 taxa were more active under fluctuating than static conditions, compared with three taxa that were more active under static compared with fluctuating conditions. These data suggest an indigenous microbial community adapted to fluctuating redox potential.     

Facile Method for Monitoring Inhibition of Anaerobic Spore Outgrowth

A device is presented for the laboratory monitoring of spore outgrowth under controlled temperature and anaerobic conditions. Alterations in pH, redox potential, headspace composition, and optical density are followed as the activated spores grow out into vegetative cells. An interlock system allows the addition of test solutions or the removal of medium under anaerobic conditions. The device may also be used for rapid (<4 h) chemical inhibition studies or adapted for temperature injury studies of aerobic or anaerobic cells. Data on outgrowth of Clostridium sporogenes and inhibition by nitrite solutions are presented.     

Effect of Carnosine on Self-Organization of Mitochondrial Assemblies in Rat Liver Homogenate

The effect of carnosine on self-organization of mitochondrial assemblies was studied in rat liver homogenate of quiescent and excited animals. It was shown in separate electron microscopy experiments with serial slices that under our conditions of preparation of homogenate, blocks of native mitochondrial-reticular network in the cell, assemblies of mitochondria, are kept. Carnosine was shown to prevent dissociation of assemblies during storage. Its effect is maximal for more dissociated assemblies from excited animals with decreased ability for self-organization. Prevention of disassembly of organelles by carnosine can serve as one of the mechanisms of carnosine-induced diminishing of muscle fatigue under prolonged work.     

Studies on well coupled Photosystem I-enriched subchloroplast vesicles. Optimization of ferredoxin-mediated cyclic photophosphorylation and electric potential generation

Optimal conditions for cyclic photophosphorylation and electric potential generation have been established in well coupled Photosystem (PS)I-enriched subchloroplast vesicles supplemented with ferredoxin. Using NADPH and oxygen as redox-poising agents, it is shown that accurate redox poising of the cyclic system is required for optimal electron transfer. The molar ratio of NADPH to oxygen, rather than their concentrations, regulates the rate of cyclic photophosphorylation. In the present experimental system, the actual redox potential of ferredoxin is of crucial importance for optimal cyclic electron transfer and energy transduction. Under conditions for optimal redox poising of the cyclic system, a relatively strong expression of the flash-induced slow electric potential component was found, as monitored by the absorption changes of carotenoids and of oxonol VI. The function and regulation of cyclic electron transfer in stroma lamellae membranes in vivo are discussed in view of the lateral heterogeneity of redox components in chloroplast membranes.     

Dynamics of the redox potential in a fed-batch culture of E. coli

Dynamics of Eh, pH, pO2 and optical density in E. coli cultures under glucose and ammonium exhaustion were studied. It has been shown that changes in the redox potential accompanying the exhaustion of these substances in aerobic cultures are the leaps by their character and reflect the physiological state of cells and changes in the structure of cell surface. A relationship between the changes in the redox potential and in the electrochemical potential of H ions (delta mu H) is suggested.     

The effect of lead incorporation on the elemental composition of earthworm (Annelida, Oligochaeta) chloragosome granules

The elemental compositions of chloragosome 'granules' in the earthworm Lumbricus rubellus living in non-polluted (Dinas Powys) and heavily Pb-polluted (Wemyss) soils were determined by fully quantitative electron probe X-ray microanalysis. P, Ca, S and Zn were the major elemental components of the chloragosomes. High Pb concentrations were found in chloragosomes of Wemyss animals; Pb was not detected in chloragosomes of Dinas Powys animals. Partial correlation and regression analysis indicated that the in vivo accumulation of Pb by chloragosomes was accompanied by diminished chloragosomal Ca concentrations. Pb is bound by P-containing ligand(s) in the chloragosome matrix. The sequestration of Pb by chloragosomes results in the detoxification of the metal by accumulative immobilization.     

The Potential of Photochemical Transition Metal Reactions in Prebiotic Organic Synthesis. I. Observed Conversion of Methanol into Ethylene Glycol as Possible Prototype for Sugar Alcohol Formation

Photochemical processes involving redox reactions between metal ions and organic substrates possess the versatile potential for having harnessed solar energy for prebiotic organic synthesis. The present study in our Laboratory has shown that ultraviolet irradiation of transition metal ions such as of Ni, Co, Fe, Cu and Ti dissolved in primary or secondary alcohols causes photoreduction of the metal ions with the concomitant oxidation of the alcohol to aldehyde or ketone. An observed accompaniment of this novel 'light' reaction has been the known 'dark' pinacol reaction, whereby the carbonyl derivative underwent bimolecular coupling to the diol by the photogenerated reduced transition metal reagent. These tandem 'light-dark' processes possess the potential for the stepwise synthesis of dimeric 1,2-diols from simpler alcohols under conditions that might have prevailed on the prebiotic earth. Experiments reported here have demonstrated that such a tandem 'light-dark' conversion of methanol into ethylene glycol, via formaldehyde, does in fact occur, when nickel(II) acetylacetonate solutions in methanol undergo prolonged irradiation at 185-254 nm. Since ethylene glycol can be considered as the simplest sugar alcohol, these findings may provide novel insight into the prebiotic oligomerization of formaldehyde into higher sugar alcohols or even sugars.     

Short-lived delayed luminescence of photosynthetic organisms. I. Nanosecond afterglows in purple bacteria at low redox potentials.

A combined study of emissions of purple bacteria Rhodospirillum rubrum, Ectothiorhodospira shaposhnikovii and Thiocapsa roseopersicina was performed under conditions of low potential. It has been shown that a considerable part of the emission represents a delayed luminescence with a lifetime of about 5 ns and an activation energy delta E = 0.05 +/- 0.03 eV. Intensity of this delayed luminescence is approximately equal to that of prompt fluorescence. It diminishes as temperature decreases and also as the intermediate acceptor I becomes reduced after prolonged illumination under low potential conditions. This luminescence represents a radiative decay of the intermediate state, PF, and the luminescence activation energy, delta E, reflects the energy barrier between P*-890 and PF. The value of this barrier determined in the present work is much lower than those obtained previously [3,4,26] for the free-energy release during the primary act of charge separation, basing on redox potential techniques. The reason for this discrepancy is discussed. Delayed luminescence in the picosecond time range is predicted to exist under conditions of active photosynthesis as a result of a small (approx. 0.05 eV) energy barrier between PF and the excited singlet state of reaction center bacteriochlorophyll.     

Regulation of 3-hydroxybutyrate formation and secretion of very-low-density-lipoprotein triacylglycerol by perfused livers from fed and starved rats.

Acetoacetate was the sole ketone body formed when livers from starved rats were perfused with minimal concentrations of non-esterified fatty acid. Absence of 3-hydroxybutyrate was related to a low substrate potential, which caused a more oxidized redox state and a decreased [ATP]/[ADP] ratio. Only under conditions of comparable non-esterified fatty acid uptake was lipoprotein triacylglycerol production inversely related to ketogenesis.     

Lysosomal origin of the chloragosomes in the chloragogenous tissue of the earthworm Eisenia foetida: cytochemical demonstration of acid phosphatase activity

Summary The cytochemical localization of the lysosomal marker enzyme acid phosphatase was studied in the chloragogenous tissue of earthworms. The Gomori lead technique and the cerium capture technique were utilized. Both techniques demonstrated the chloragosomal location of this enzyme. Only a small proportion of chloragosomes presented reactivity, which suggests that these organelles are distinctly heterogeneous. The reaction product was localized in the periphery of chloragosomes, suggesting a membrane-bound compartmentalization of acid phosphatase. In addition, degenerating mitochondria and membrane whorls were observed in some chloragosomes, indicating the possibility that these organelles perform autophagosomal functions.