Respiration-linked proton translocation coupled to anaerobic reduction of manganese(IV) and iron(III) in Shewanella putrefaciens MR-1.

An oxidant pulse technique, with lactate as the electron donor, was used to study respiration-linked proton translocation in the manganese- and iron-reducing bacterium Shewanella putrefaciens MR-1. Cells grown anaerobically with fumarate or nitrate as the electron acceptor translocated protons in response to manganese (IV), fumarate, or oxygen. Cells grown anaerobically with fumarate also translocated protons in response to iron(III) and thiosulfate, whereas those grown with nitrate did not. Aerobically grown cells translocated protons only in response to oxygen. Proton translocation with all electron acceptors was abolished in the presence of the protonophore carbonyl cyanide m-chlorophenylhydrazone (20 microM) and was partially to completely inhibited by the electron transport inhibitor 2-n-heptyl-4-hydroxyquinoline N-oxide (50 microM).     

Nitric oxide-dependent proton translocation in various denitrifiers.

Respiration of NO resulted in transient proton translocation in anaerobically grown cells of four physiologically diverse denitrifiers. Paracoccus denitrificans, Rhodopseudomonas sphaeroides subsp. denitrificans, "Achromobacter cycloclastes," and Rhizobium japonicum gave, respectively, H+/NO ratios of 3.65, 4.96, 1.94, and 1.12. Antimycin A completely inhibited NO-dependent proton translocation in P. denitrificans and severely restricted translocation in the R. sphaeroides strain. Proton uptake during NO respiration with antimycin A-inhibited cells supplied with an artificial electron source provided evidence for the periplasmic consumption of protons. Values obtained were consistent with the expected ratios of 0.5 mol of H+/mol of NO for reduction of NO to N2O and 1.0 mol of H+/mol of NO for reduction of NO to N2. These data are consistent with the presence of a unique NO reductase found only in anaerobically grown denitrifying cells.     

An ATP-driven proton pump in clathrin-coated vesicles

Clathrin containing coated vesicles prepared from bovine brain catalyzed ATP-driven proton translocation and a 32Pi-ATP exchange reaction. Both activities were measured in the presence of 5 micrograms of oligomycin/mg of protein which completely inhibited these reactions catalyzed by submitochondrial particles. Analyses performed during the purification procedure demonstrated that the oligomycin-resistant pump was concentrated and highly purified in the fractions containing coated vesicles. Moreover, vesicles precipitated by either monoclonal or polyclonal antibodies against clathrin contained the H+ pump activity. Dicyclohexylcarbodiimide (0.5 mM) and N-ethylmaleimide (1 mM) added to the assay mixture inhibited the pump completely, whereas neither vanadate, sodium azide, efrapeptin, or mitochondrial ATPase inhibitor had an effect.     

Proton translocation coupled to the oxidation of carbon monoxide to CO2 and H2 in Methanosarcina barkeri

Cell suspensions of acetate-grown Methanosarcina barkeri mediate the conversion of CO and H2O to CO2 and H2. The reaction is coupled with the phosphorylation of ADP. Evidence is presented that CO oxidation by the cells is associated with the transient acidification of the suspension medium. Up to 2 mol vectorial protons were measured/mol CO oxidized when the transmembrane electrical gradient was kept low by the addition of valinomycin (20 nmol/mg protein) and KCl (200 mM) or of KSCN (50 mM). No transient acidification was observed in the presence of the protonophore tetrachlorosalicylanilide which stimulated rather than inhibited CO oxidation. Proton extrusion remained unaltered when the proton-translocating ATPase was specifically inhibited by dicyclohexylcarbodiimide. The latter finding indicates that proton translocation is associated with CO conversion to CO2 and H2 rather than with ATP hydrolysis in the cells. The data substantiate that the coupling of CO oxidation with ADP phosphorylation in M. barkeri occurs via a chemiosmotic mechanism.     

Energy transduction in the mitochondrionlike bacterium Paracoccus denitrificans during carbon- or sulphate-limited aerobic growth in continuous culture.

Paracoccus denitrificans was grown in carbon-limited aerobic continuous culture (critical dilution rate (Dc) = 0.48 h-1). The molar growth yield for carbon (succinate or malate) was constant at about 60 over a broad dilution range (growth rate) from 0.10 to 0.48 h-1. Measurements of the stoichiometry of proton translocation associated with the oxidation of endogenous substrates yielded a ratio of protons ejected from the cell per atom of oxygen consumed(leads to H+:O) of 8.55 which decreased to 5.85 in the presence of piericidin A (PA), a specific inhibitor of NADH dehydrogenase (EC 1.6.99.3). With starved cells, the observed leads to H+:O associated with the oxidation of added succinate in the presence of PA was 5.61. These observed leads to H:O's represent an underestimation since no correction was made for proton backflow during the short interval of respiratory activity. Aerobic growth of Pc. denitrificans in the chemostat becomes sulphate limited at entering concentrations of sulphate less than 300 is microM. Neither the maximum specific growth rate (measured at Dc) nor the observed molar growth yield for succinate decreased under sulphate limitation. The NADH oxidase in electron transport particles prepared from sulphate-limited cells was completely inhibited by PA. The stoichiometry of proton translocation associated with malate oxidation was similarly unaffected by sulphate limitation. It is concluded that (a) the respiratory chain of aerobic, heterotrophically grown Pc. denitrificans possesses three sites of energy conservation, including site III, (b) the number of protons ejected during the transfer of one pair of reducing equivalents along a region of the electron transport chain equivalent to a single energy-coupling site is 3, and (c) that sulphate limitation does not lead to a loss of proton translocation associated with the cytochrome-independent region of the respiratory chain.     

Structural elements involved in proton translocation by cytochrome c oxidase as revealed by backbone amide hydrogen-deuterium exchange of the E286H mutant

Cytochrome c oxidase is the terminal electron acceptor in the respiratory chains of aerobic organisms and energetically couples the reduction of oxygen to water to proton pumping across the membrane. The mechanisms of proton uptake, gating, and pumping have yet to be completely elucidated at the molecular level for these enzymes. For Rhodobacter sphaeroides CytcO (cytochrome aa3), it appears as though the E286 side chain of subunit I is a branching point from which protons are shuttled either to the catalytic site for O2 reduction or to the acceptor site for pumped protons. Amide hydrogen-deuterium exchange mass spectrometry was used to investigate how mutation of this key branching residue to histidine (E286H) affects the structures and dynamics of four redox intermediate states. A functional characterization of this mutant reveals that E286H CytcO retains approximately 1% steady-state activity that is uncoupled from proton pumping and that proton transfer from H286 is significantly slowed. Backbone amide H-D exchange kinetics indicates that specific regions of CytcO, perturbed by the E286H mutation, are likely to be involved in proton gating and in the exit pathway for pumped protons. The results indicate that redox-dependent conformational changes around E286 are essential for internal proton transfer. E286H CytcO, however, is incapable of these specific conformational changes and therefore is insensitive to the redox state of the enzyme. These data support a model where the side chain conformation of E286 controls proton translocation in CytcO through its interactions with the proton gate, which directs the flow of protons either to the active site or to the exit pathway. In the E286H mutant, the proton gate does not function properly and the exit channel is unresponsive. These results provide new insight into the structure and mechanism of proton translocation by CytcO.     

In vitro translocation of protein across Escherichia coli membrane vesicles requires both the proton motive force and ATP

The energy requirement for protein translocation across membrane was studied with inverted membrane vesicles from an Escherichia coli strain that lacks all components of F1F0-ATPase. An ompF-lpp chimeric protein was used as a model secretory protein. Translocation of the chimeric protein into membrane vesicles was totally inhibited in the presence of carbonyl cyanide m-chlorophenylhydrazone (CCCP) or valinomycin and nigericin and partially inhibited when either valinomycin or nigericin alone was added. Depletion of ATP with glucose and hexokinase resulted in the complete inhibition of the translocation process, and the inhibition was suppressed by the addition of ATP-generating systems such as phosphoenolpyruvate-pyruvate kinase or creatine phosphate-creatine kinase. These results indicate that both the proton motive force and ATP are required for the translocation process. The results further suggest that both the membrane potential and the chemical gradient of protons (delta pH), of which the proton motive force is composed, participate in the translocation process.     

Effect of phytohormones on the transmembrane translocation of protons in plasma membrane vesicles from tubers of Solanum tuberosum L

Effects of phytohormones gibberellic acid (GA) and abscisic acid (ABA) on the ATP-dependent transmembrane transport of protons were studied in plasma membrane vesicles (PMVs) from non-dormant potato tubers. The uptake of H+ into PMVs was assessed by the fluorescence quenching of acridine orange (AO) after the addition of ATP to the incubation medium. Addition of ATP to the incubation medium led to the instantaneous rise of the AO fluorescence intensity followed by its decrease. The fluorescence quenching was not observed in the presence of either protonophore CCCP or inhibitors of the membrane-bound H+-ATPase. It is concluded that the ATP-induced quenching of the AO fluorescence resulted from the accumulation of protons in PMVs due to the function of the plasma membrane-bound H+-ATPase. Depending on their concentrations, GA and ABA either inhibited or stimulated the ATP-driven H+ translocation across the vesicle membrane. The growth-stimulating hormone GA at concentrations of 10(-9)-10(-5) M increased the initial rate of the fluorescence quenching, whereas 10(-4) M GA slightly inhibited the H+ translocation. The growth inhibitor ABA at a concentration of 10(-9) M slightly increased the rate of the proton accumulation in PMVs; at higher concentrations (10(-8)-10(-4) M), ABA inhibited the H+ translocation. Acetic acid, which has pK similar to pK of GA and ABA, did not influence the ATP-dependent H+ accumulation in PMVs, suggesting the hormone-specific action of GA and ABA on the H+-ATPase activity. In the presence of DCC, which completely inhibited the accumulation of H+, GA and ABA did not affect the passive proton efflux from PMVs. It is proposed that the mechanisms of the regulatory effects of phytohormones may involve modification of H+-ATPase activity leading to changes in the electrochemical gradient of H+ across the plasma membrane.     

Respiration-linked proton flux in Wolinella succinogenes during reduction of N-oxides

Formate uncoupled proton translocation in formate-grown Wolinella succinogenes cells supplied with N-oxides as terminal electron acceptors. In suspensions containing KSCN (but not valinomycin), H2 supported proton translocation when NO3-, NO2-, and NO were provided as oxidants. H+/N-oxide ratios were 4.77 for NO3-, 2.49 for NO2-, and 1.75 for NO. KSCN inhibits N2O reduction thus precluding use of N2O as oxidant. Repeated exposure of cells to NO inhibited their ability to translocated protons with NO as oxidant but only slightly diminished and did not eliminate their capacity for NO3(-)- or NO2(-)-dependent proton flux. Substituting reduced benzyl viologen for H2 and measuring proton uptake provided results consistent with an extramembranal location for the N- oxide reductases. The uncoupler, carbonyl cyanide m-chlorophenylhydrazone, collapsed proton gradients, permitted uptake of 2 mol H+/mol NO3- or NO2-, but unaccountably inhibited NO3- reduction by 50% while leaving H+ uptake stoichiometry of the cells unaffected.     

Sugar uptake and proton release by protoplasts from the infected zone of Vicia faba L. nodules: evidence against apoplastic sugar supply of infected cells

Symbiotic dinitrogen fixation of legume nodules is fuelled by phloem-imported carbohydrates. These have to pass several cell layers to reach cells infected with Rhizobium bacteroids. It is unclear whether apoplastic steps are involved in carbohyd-rate translocation within the nodule. Protoplasts were isolated from the infected and uninfected cells of the central tissue of Vicia faba nodules using a recently developed protocol. These protoplasts were used to elucidate pathways for sugar transport in this tissue. Both types of protoplasts released protons into the medium. Acidification was inhibited by vanadate and erythrosin B. However, it was stimulated by fusicoccin only in uninfected cells. A symport of sugars with protons can therefore be energized in both cell types. Uptake of 14C-labelled sugars was determined using a phthalate centrifugation technique. Uninfected protoplasts accumulated glucose through high-affinity H+/glucose-symport that was not competitively inhibited by fructose or sucrose. Uninfected protoplasts also absorbed sucrose with biphasic kinetics. At 0.1, 1, and 10 mM sucrose, uptake was inhibited by CCCP. Fusicoccin did not stimulate the linear phase of sucrose uptake. Glucose inhibited sucrose uptake nearly completely. This was not related to sucrose cleavage in the medium because sucrose was absorbed at a much higher rate than glucose, and glucose concentration did not increase in sucrose-containing protoplast suspensions. By contrast with uninfected protoplasts, infected cells did not show transporter-mediated glucose or sucrose uptake. The findings underline a role of uninfected cells in sugar translocation. Infected cells are not apoplastically supplied with sugars and possibly depend on uninfected cells for carbon supply.     

Energy dependence of lipopolysaccharide translocation in Salmonella typhimurium

Energy inhibitors block translocation of pulse-labeled core lipopolysaccharide to outer membrane under conditions which allow maintenance of constant specific radioactivity of intracellular precursor pools throughout the chase period. Under the conditions used, approximately 75% of the total cellular label was membrane-bound at initiation of chase. Translocation of core lipopolysaccharide from inner to outer membrane showed apparent first order kinetics (t1/2 = 1.2 min, 32 degrees C). Translocation was blocked by arsenate (5-10 mM) under conditions where proton motive force was unchanged, while the uncouplers 2,4-dinitrophenol (0.1 mM to 0.8 mM) and carbonyl cyanide-m-chlorophenyl hydrazone (12-30 microM) inhibited translocation with no apparent effect on the ATP pool. Therefore, core lipopolysaccharide translocation appears to require maintenance of both proton motive force and high energy phosphate pools. Electron microscopic experiments show no gross disruption of zones of adhesion, the putative sites of lipopolysaccharide translocation, in the presence of arsenate or 2,4-dinitrophenol suggesting that energy is not required simply for maintenance of these structures.     

Thiocyanate and nitrite inhibit proton translocation in gastric mucosa

Isolated frog gastric mucosa was used to study the separation of formation of protons (or their precursors) from proton translocation by using various inhibitors. Both thiocyanate (SCN-) and nitrite (NO2-) inhibit the acid secretion in spontaneously secreting mucosa. The inhibition is reversed when the inhibitor is removed such that the excess acid secreted above baseline in the 'off'-period compensates for the amount inhibited in the 'on'-period. Both agents also inhibit the effect on acid secretion of pulse stimulation with histamine though to a lesser extent. Upon removal of the inhibitor, the total amount of acid secreted in excess of basal is equal to that observed with histamine alone. Likewise, metiamide, an H2-antagonist, also inhibits acid secretion with or without histamine. However, in contrast to SCN- and NO2-, removal of this inhibitor is without effect on the acid-secretion rate. These results indicate that both SCN- and NO2- inhibit the proton translocation rather than the formation of protons or their precursors as is the case with metiamide.     

Mechanisms of hydrogen peroxide formation in leukocytes: the NAD(P)H oxidase activity of myeloperoxidase.

The NADPH oxidase activity of polymorphonuclear leukocyte granules has not previously been attributed to myeloperoxidase because of its relative insensitivity to cyanide and its activation by aminotriazole. However it has been found that the NAD(P)H oxidase activity of myeloperoxidase or horseradish peroxidase was little affected by 2.0 mM cyanide although the peroxidase activity was nearly completely inhibited by 0.1 mM cyanide. Furthermore, the NAD(P)H oxidase activity of myeloperoxidase was considerably enhanced by aminotriazole although the peroxidase activity was inhibited.     

Proton translocation coefficient for H+-ATPase of rat liver mitochondria

Some features of H+-ATPase function in intact mitochondria of rat liver were studied. Simultaneously the activities of ATPase and proton translocase were measured, using a previously described technique. The proton translocation coefficient of H+-ATPase has been found to be equal to 3.6. The protonophore 3.5-di-tert-butyl-4-hydroxybenzylidenemalononitrile diminishes the proton translocation coefficient. It was concluded that when considering the mechanism of proton translocation by H+-ATPase, it is necessary to assume the possibility of transport of 3 or 4 protons per every hydrolyzed molecule of ATP allowing a changeable efficiency of the process. The decrease of the translocase coefficient in the presence of the protonophore appears to result from the ability of this uncoupler to return the transferred protons to the mitochondrial matrix.     

Chloride transport of yeast vacuolar membrane vesicles: a study of in vitro vacuolar acidification.

Effects of various solutes on acidification inside the vacuolar membrane vesicles of the yeast Saccharomyces cerevisiae were examined. ATP-dependent acidification was stimulated by the presence of chloride salts. There was essentially no difference in the stimulatory effects of NaCl, KCl, LiCl, and choline chloride. The membrane potential across the vacuolar membrane was reduced by the presence of Cl- salts. Transport of 36Cl- is driven by the protonmotive force across the vacuolar membrane. Kinetic analyses have revealed that the stimulatory effect of Cl- on internal acidification depends on two distinct components. One shows linear dependency on chloride concentration and is inhibited by 4,4'-diisothiocyano-2,2'-stilbenedisulphonic acid (DIDS). The other exhibits saturable kinetics with an apparent Km for chloride of 15-20 mM. We conclude that the vacuolar membrane of yeast is equipped with Cl- transport systems contributing to the formation of a chemical gradient of protons across the vacuolar membrane by shunting the membrane potential generated by proton translocation.     

Pyrophosphate-induced acidification of trans cisternal elements of rat liver Golgi apparatus.

Trans cisternal elements of the Golgi apparatus from rat liver, identified by thiamin pyrophosphatase cytochemistry, were isolated by preparative free-flow electrophoresis and were found to undergo acidification as measured by a spectral shift in the absorbance of acridine orange. Acidification was supported not only by adenosine triphosphate (ATP) but nearly to the same degree by inorganic pyrophosphate (PPi). The proton gradients generated by either ATP or PPi were collapsed by addition of a neutral H+/K+ exchanger, nigericin, or the protonophore, carbonyl cyanide m-chlorophenylhydrazone, both at 1.5 microM. Both ATP hydrolysis and ATP-driven proton translocation as well as pyrophosphate hydrolysis and pyrophosphate-driven acidification were stimulated by chloride ions. However, ATP-dependent activities were optimum at pH 6.6, whereas pyrophosphate-dependent activities were optimum at pH 7.6. The Mg2+ optima also were different, being 0.5 mM with ATP and 5 mM with pyrophosphate. With both ATPase and especially pyrophosphatase activity, both by cytochemistry and analysis of free-flow electrophoresis fractions, hydrolysis was more evenly distributed across the Golgi apparatus stack than was either ATP- or PPi-induced inward transport of protons. Proton transport colocalized more closely with thiamin pyrophosphatase activity than did either pyrophosphatase or ATPase activity. ATP- and pyrophosphatase-dependent acidification were maximal in different electrophoretic fractions consistent with the operation of two distinct proton translocation activities, one driven by ATP and one driven by pyrophosphate.     

Proton release associated with respiratory burst of polymorphonuclear leukocytes

The stimulation of polymorphonuclear leukocytes (PMNs) by phorbol-12-myristate-13-acetate in the presence of sodium fluoride caused the release of protons into the reaction medium concomitant with the generation of superoxide anions. The rates of oxygen consumption and proton release due to the metabolic burst were 16.3 +/- 3.5 and 10.2 +/- 1.1 nmol/min/10(7) cells respectively. When the superoxide anions were trapped with cytochrome c, the proton release was increased (35.8 +/- 0.5 nmol/min/10(7) cells) until the cytochrome c was reduced. Since the protons released from the activated cells would be consumed by the generated superoxide anions in the extracellular medium, the net amount of the protons released was 3-4-fold greater than that observed in the absence of extracellular cytochrome c. The increased proton release may be coupled to increased cellular respiration, since the inhibition of the respiratory burst with deoxyglucose, p-chloromercuribenzoic acid or chlorpromazine decreased the proton release. Amiloride (2 mM) inhibited the proton release by up to 40%. These observations suggest that some mechanisms other than a Na+/H+ antiport and carbon dioxide diffusion could be transporting the H+ generated in the cytosol of the activated PMNs.     

Modulation of extracellular proton fluxes from retinal horizontal cells of the catfish by depolarization and glutamate

Self-referencing H(+)-selective microelectrodes were used to measure extracellular proton fluxes from cone-driven horizontal cells isolated from the retina of the catfish (Ictalurus punctatus). The neurotransmitter glutamate induced an alkalinization of the area adjacent to the external face of the cell membrane. The effect of glutamate occurred regardless of whether the external solution was buffered with 1 mM HEPES, 3 mM phosphate, or 24 mM bicarbonate. The AMPA/kainate receptor agonist kainate and the NMDA receptor agonist N-methyl-D-aspartate both mimicked the effect of glutamate. The effect of kainate on proton flux was inhibited by the AMPA/kainate receptor blocker CNQX, and the effect of NMDA was abolished by the NMDA receptor antagonist DAP-5. Metabotropic glutamate receptor agonists produced no alteration in proton fluxes from horizontal cells. Depolarization of cells either by increasing extracellular potassium or directly by voltage clamp also produced an alkalinization adjacent to the cell membrane. The effects of depolarization on proton flux were blocked by 10 microM nifedipine, an inhibitor of L-type calcium channels. The plasmalemma Ca(2+/)H(+) ATPase (PMCA) blocker 5(6)-carboxyeosin also significantly reduced proton flux modulation by glutamate. Our results are consistent with the hypothesis that glutamate-induced extracellular alkalinizations arise from activation of the PMCA pump following increased intracellular calcium entry into cells. This process might help to relieve suppression of photoreceptor neurotransmitter release that results from exocytosed protons from photoreceptor synaptic terminals. Our findings argue strongly against the hypothesis that protons released by horizontal cells act as the inhibitory feedback neurotransmitter that creates the surround portion of the receptive fields of retinal neurons.     

Photosynthetic Electron Transport Involved in PxcA-Dependent Proton Extrusion in Synechocystis sp. Strain PCC6803: Effect of pxcA Inactivation on CO2, HCO3−, and NO3− Uptake

The product of pxcA (formerly known as cotA) is involved in light-induced Na⁺-dependent proton extrusion. In the presence of 2,5-dimethyl-p-benzoquinone, net proton extrusion by Synechocystis sp. strain PCC6803 ceased after 1 min of illumination and a postillumination influx of protons was observed, suggesting that the PxcA-dependent, light-dependent proton extrusion equilibrates with a light-independent influx of protons. A photosystem I (PS I) deletion mutant extruded a large number of protons in the light. Thus, PS II-dependent electron transfer and proton translocation are major factors in light-driven proton extrusion, presumably mediated by ATP synthesis. Inhibition of CO₂ fixation by glyceraldehyde in a cytochrome c oxidase (COX) deletion mutant strongly inhibited the proton extrusion. Leakage of PS II-generated electrons to oxygen via COX appears to be required for proton extrusion when CO₂ fixation is inhibited. At pH 8.0, NO₃⁻ uptake activity was very low in the pxcA mutant at low [Na⁺] (~100 μM). At pH 6.5, the pxcA strain did not take up CO₂ or NO₃⁻ at low [Na⁺] and showed very low CO₂ uptake activity even at 15 mM Na⁺. A possible role of PxcA-dependent proton exchange in charge and pH homeostasis during uptake of CO₂, HCO₃⁻, and NO₃⁻ is discussed.     

Mechanisms of generation of local ΔpH in mitochondria and bacteria

The concepts of global and local coupling between proton generators, the enzymes of the respiratory chain, and the consumer, the ATP synthase, coexist in the theory of oxidative phosphorylation. Global coupling is trivial proton transport via the aqueous medium, whereas local coupling implies that the protons pumped are consumed before they escape to the bulk phase. In this work, the conditions for the occurrence of local coupling are explored. It is supposed that the membrane retains protons near its surface and that the proton current generated by the proton pumps rapidly decreases with increasing proton motive force (pmf). It is shown that the competition between the processes of proton translocation across the membrane and their dissipation from the surface to the bulk can result in transient generation of a local ΔpH in reply to a sharp change in pmf; the appearance of local ΔpH, in turn, leads to rapid recovery of the pmf, and hence, it provides for stabilization of the potential at the membrane. Two mechanisms of such kind are discussed: 1) pH changes in the surface area due to proton pumping develop faster than those due to proton escape to the bulk; 2) the former does not take place, but the protons leaving the surface do not equilibrate with the bulk immediately; rather, they give rise to a non-equilibrium concentration near the surface and, as a result, to a back proton flow to the surface. The first mechanism is more efficient, but it does not occur in mitochondria and neutrophilic bacteria, whereas the second can produce ΔpH on the order of unity. In the absence of proton retardation at the surface, local ΔpH does not arise, whereas the formation of global ΔpH is possible only at buffer concentration of less than 10 mM. The role of the mechanisms proposed in transitions between States 3 and 4 of the respiratory chain is discussed. The main conclusion is that surface protons, under conditions where they play a role, support stabilization of the membrane pmf and rapid communication between proton generators and consumers, while their contribution to the energetics is not significant.