Some Experiments and Conclusions about the Influence of Pure H2 Gason the Anaerobic Degradation of Propionate by Mixed Cultures

Reaction enthalpy for propionate degradationΔG₀ is only negative when the partial pressure ofhydrogen pH₂ is less than 10^—4 bar. This means that for pH₂ more than 10^—4 bar, a total anaerobic degradation of propionate is impossible for thermodynamic reasons. Therefore, with increasing pH₂, the anaerobic degradation rate of propionate via acetate is inhibited. There are two ways to investigate the inhibitory effect of pH₂: to keep the concentration of hydrogen consuming bacteria low or to increase the mass transfer by feeding the hydrogen at higher flow rates. The author used an extended fixed bed reactor filled with polyurethane particles as a carrier for the bacteria, aerated with pure H₂ gas. The results, compared with the literature by using model equations in order to standardize the data, correspond well: The addition of pure H₂ gas has no observable effects on propionate degradation.In the fixed bed reactor with immobilized bacteria, it was not possible to reach an inhibitory concentration of H₂ and high process stability could be maintained.     

Iron-nutritional aspects of the ionic balance of plants

Summary The effect of iron on the ionic balance of several plant species and cultivars was studied. Those plants which normally excrete relatively low amounts of hydroxyl ions respond to iron stress by lowering the pH of the nutrient medium and decreasing anion uptake. These plants may be considered as being Fe efficient. Plants which normally excrete relatively high amounts of hydroxyl ions and which continue to increase the pH of a nutrient medium when under iron stress may be considered as Fe inefficient.Iron deficiency tends to increase carboxylate accumulation and to decrease anion uptake. When cation uptake is depressed by iron deficiency this is mainly a non specific depression of potassium uptake, on the other hand when iron stress stimulates cation uptake this is mainly due to a specific stimulation of the divalent cations Ca and Mg.Additional key words: Iron, efficiency of uptake, ionic balance, hydroxyl and hydrogen ion excretion.     

Altered proton extrusion in cells adapted to growth at low extracellular pH

Intracellular pH (pH_i) homeostasis is crucial to cell survival. Cells that are chronically exposed to a low pH environment must adapt their hydrogen ion extrusion mechanisms to maintain their pH_i in the physiologic range. An important component of the adaptation to growth at low pH is the upregulation of pH_i relative to the extracellular pH (pH_e). To test the ability of low pH_e adapted cells to respond to a pH_i lowering challenge, a fluorescence assay was used that directly monitors proton removal as the rate of change of pH_i during recovery from cytosolic acidification. Two cell lines of Chinese hamster origin (ovarian carcinoma and ovary fibroblastoid cells) were compared, both of which showed altered proton extrusion after adaptation to growth at low pH_e = 6.70. In the ovarian carcinoma (OvCa) cell line, the pattern was consistent with an upregulation by means of an increase in the number of functional proton transporters in the plasma membrane. In the ovary fibroblastoid (CHO-10B) cell line, pH_i was consistently elevated in adapted cells as compared with cells grown at normal pH_e = 7.30 without an increase in maximum extrusion rate. This upregulation was consistent with a shift in the activating pH_i of proton transporters without an increase in the number of transporters, i.e., a change in substrate affinity of the transporter. In OvCa cells, recovery from acidification could be blocked by amiloride, an inhibitor of Na⁺/H⁺ exchange. In contrast, a more modest effect of amiloride on CHO cells was observed but a complete inhibition was seen with the Cl⁻/HCO⁻₃ exchange inhibitor 4,4′-diisothiocyanatostilbene-2,2′-disulfonic acid (DIDS). These data indicate that the two cell lines rely to different degrees on the two major pathways for pH regulation during recovery from cytosolic acidification. J. Cell. Physiol. 173:397–405, 1997. © 1997 Wiley-Liss, Inc.     

Microsensor studies on Padina from a natural CO2 seep: implications of morphology on acclimation to low pH

Low seawater pH can be harmful to many calcifying marine organisms, but the calcifying macroalgae Padina spp. flourish at natural submarine carbon dioxide seeps where seawater pH is low. We show that the microenvironment created by the rolled thallus margin of Padina australis facilitates supersaturation of CaCO₃ and calcifi‐cation via photosynthesis‐induced elevated pH. Using microsensors to investigate oxygen and pH dynamics in the microenvironment of P. australis at a shallow CO₂ seep, we found that, under saturating light, the pH inside the microenvironment (pH_ME) was higher than the external seawater (pH_SW) at all pH_SW levels investigated, and the difference (i.e., pH_ME ? pH_SW) increased with decreasing pH_SW (0.9 units at pH_SW 7.0). Gross photosynthesis (P_g) inside the microenvironment increased with decreasing pH_SW, but algae from the control site reached a threshold at pH 6.5. Seep algae showed no pH threshold with respect to P_g within the pH_SW range investigated. The external carbonic anhydrase (CA) inhibitor, acetazolamide, strongly inhibited P_g of P. australis at pH_SW 8.2, but the effect was diminished under low pH_SW (6.4–7.5), suggesting a greater dependence on membrane‐bound CA for the dehydration of HCO₃^? ions during dissolved inorganic carbon uptake at the higher pH_SW. In comparison, a calcifying green alga, Halimeda cuneata f. digitata, was not inhibited by AZ, suggesting efficient bicarbonate transport. The ability of P. australis to elevate pH_ME at the site of calcification and its strong dependence on CA may explain why it can thrive at low pH_SW.     

The Final Frontier of pH and the Undiscovered Country Beyond

The comparison of volumes of cells and subcellular structures with the pH values reported for them leads to a conflict with the definition of the pH scale. The pH scale is based on the ionic product of water, K _w = [H⁺]×[OH⁻].We used K _w [in a reversed way] to calculate the number of undissociated H₂O molecules required by this equilibrium constant to yield at least one of its daughter ions, H⁺ or OH⁻ at a given pH. In this way we obtained a formula that relates pH to the minimal volume V_pH required to provide a physical meaning to K _w, (where N _A is Avogadro’s number). For example, at pH 7 (neutral at 25°C) V_pH = 16.6 aL. Any deviation from neutral pH results in a larger V_pH value. Our results indicate that many subcellular structures, including coated vesicles and lysosomes, are too small to contain free H⁺ ions at equilibrium, thus the definition of pH based on K _w is no longer valid. Larger subcellular structures, such as mitochondria, apparently contain only a few free H⁺ ions. These results indicate that pH fails to describe intracellular conditions, and that water appears to be dissociated too weakly to provide free H⁺ ions as a general source for biochemical reactions. Consequences of this finding are discussed.     

Surface pH at the Basolateral Membrane of the Caecal Mucosa of Guinea Pig

Since the major mechanisms responsible for regulation of intracellular pH of enterocytes are located in the basolateral membrane, respective effects may be expected on pH in the compartment near the basolateral membrane. A method was established to estimate the pH at the basolateral membrane (pH _b ) of isolated caecal epithelia of guinea pig using pH-sensitive fluorescein attached to lectin (lens culinaris). In the presence of bicarbonate and a perfusion solution-pH of 7.4, pH _b was 7.70 ± 0.15. In the absence of bicarbonate or chloride as well as by inhibition of the basolateral Cl⁻-HCO⁻ ₃ exchange with H₂-DIDS, pH _b was reduced near to solution-pH. Inhibition of the basolateral Na⁺-H⁺ exchanger by adding a sodium- and bicarbonate-free, low-buffered solution increased pH _b . Decrease of pH of serosal perfusion solution to 6.4 provoked a similar decrease of pH _b to solution pH. Short-chain fatty acids (SCFA) added to the mucosal solution caused a slight decrease of pH _b . SCFA added to the serosal side alkalized pH _b . However, in the presence of bicarbonate pH _b returned quickly to the initial pH _b , and after removal of SCFA a transient acidification of pH _b was seen. These responses could not be inhibited by MIA or H₂-DIDS. We conclude that no constant pH-microclimate exists at the basolateral side. The regulation of the intracellular pH of enterocytes reflects pH _b . The slightly alkaline pH _b is due to the bicarbonate efflux. Data support the presence of an SCFA⁻-HCO⁻ ₃ exchange. Received: 17 December 1998/Revised: 24 February 1999     

The effect of recrystallization of aqueous solutions of metal sulfates on the acid–base balance

A comparative study of pH values in recrystallized aqueous solutions of manganese, copper, and iron sulfates and the calculated values for the pH levels of similar solutions obtained directly from solid salts has been performed for the first time. The trend for the positive deviation of the pH_rec values from the pH_calc values has been established. The positive deviation was the strongest in the case of iron sulfate solutions. The sample of the recrystallized aqueous solution (recrystallized water) consisted of water obtained by melting of the initial aqueous solution after freezing of 60% of the solution (by volume). Four hypotheses were proposed to explain the positive deviation of pH_rec from pH_calc: (1) low СО₂ concentration; (2) more efficient adsorption of anions on the freezing front compared to that of cations; (3) mechanochemical and radiation chemical processes that occur upon the melting of ice; and (4) Fe²⁺-catalyzed decomposition of hydrogen peroxide formed in the recrystallized solution. Analysis of the putative causes showed that the fourth hypothesis provided the most adequate explanation of the difference between pH_rec and pH_calc. The formation of hydrogen peroxide in recrystallized water is proposed to occur due to the recombination of OH radicals formed during the radiation chemical processes.     

Structural changes in the cytoplasmic pore of the Kir1.1 channel during pHi-gating probed by FRET

Kir1.1 channels are important in maintaining K⁺ homeostasis in the kidney. Intracellular acidification reversibly closes the Kir1.1 channel and thus decreases K⁺ secretion. In this study, we used Foster resonance energy transfer (FRET) to determine whether the conformation of the cytoplasmic pore changes in response to intracellular pH (pH_i)-gating in Kir1.1 channels fused with enhanced cyan fluorescent protein (ECFP) and enhanced yellow fluorescent protein (EYFP) (ECFP-Kir1.1-EYFP). Because the fluorescence intensities of ECFP and EYFP were affected at pH_i < 7.4 where pH_i-gating occurs in the ECFP-Kir1.1-EYFP construct, we examined the FRET efficiencies of an ECFP-S219R-EYFP mutant, which is completed closed at pH_i 7.4 and open at pH_i 10.0. FRET efficiency was increased from 25% to 40% when the pH_i was decreased from 10.0 to 7.4. These results suggest that the conformation of the cytoplasmic pore in the Kir1.1 channel changes in response to pH_i gating such that the N- and C-termini move apart from each other at pH_i 7.4, when the channel is open.     

Sodium-hydrogen exchange and its role in controlling contractility during acidosis in cardiac muscle

Intracellular pH (pH_i) and Na (a_na ⁱ) were recorded in isolated sheep cardiac Purkinje fibres using ion-selective microelectrodes while simultaneously recording twitch tension. A fall of (pH_i) stimulated acid-extrusion via sarcolemmal Na-H exchange but the extrusion was inhibited by reducing extracellular pH (pH_o), indicating an inhibitory effect of external H ions upon the exchanger. Intracellular acidosis can reduce contraction by directly reducing myofibrillar Ca^2– sensitivity. The activation of Na-H exchange at low (pH_i) can offset this direct inhibitory effect of H^– ions since exchange-activation elevates a_na ⁱ which then indirectly elevates Ca_i ²⁺ (via Na-Ca exchange) thus tending to restore tension. This protection of contraction during intracellular acidosis can be removed if extracellular (pH_i) is also allowed to fall since, under these conditions, Na-H exchange is inhibited.     

Models for relating pH measurements in water and calcium chloride for a wide range of pH,soil types and depths

Soil pH is commonly measured in water (pHw) or 0.01 M CaCl₂ (pH_Ca). The need to convert between these methods has led to the publication of linear, quadratic and cubic polynomial relationships for limited suites of soils. Concerns over the applicability of such relationships when mapping a wide range of soils and pH led to the establishment of a database of pH_W and pH_Ca values on each of 7894 samples from soil survey and field experimental sites in Queensland. The relationship between pH_W and pH_Ca across all soils was investigated and preliminary results examining the effect of soil depth and soil type on the relationship are presented.For all soils and depths, a linear regression accounted for 93.2% of the variation but did not predict pH_Ca well at very high or low pH_W values. The inclusion of second and third powers of pH_W accounted for significantly more of the variation (R²=0.94) in pH_Ca and the resultant curve matched the data better at high and low pH.Analysis of surface, sub-surface and subsoil groupings did not reveal any appreciable differences in the relationship between pH_W and pH_Ca attributable to depth. In contrast, differences in the relationship were evident between soil types. Generally, the mildly leached soils had linear relationships, while the weathered soils were distinctly curvilinear at low pH.     

An X-ray crystallographic investigation of exchange of localized sulfate ions in crystals of α-chymotrypsin

Localized sulfate ions in the crystal structure of α-chymotrypsin have been exchanged with selenate ions. The exchange was studied using difference X-ray crystallographic methods at 2.8 Å resolution at three (SeO₄^2?:(SO₄^2?) ion ratios (5:1, 20:1, 100:1) and crystals grown from ammonium selenate. All the localized (SO₄^2? ions are exchangeable and they apparently solvate the enzyme molecule with a range of binding constants. One pair of ions is extremely facile toward the exchange. The latter occur internally at high occupancy in the interface region between the two independent molecules of the asymmetric unit and participate in a hydrogen bonding scheme that appears to be an important interaction in maintaining the dimeric structure of the crystal. These ions form hydrogen bonding bridges in a reciprocating manner between the independent molecules of the asymmetric unit of the crystal which involve the side chain of catalytically crucial Ser195 of one molecule and the phenolic hydroxyl of Tyr′146 of the other molecule; in addition, each (SeO₄^2? ion also appears to hydrogen bond with the amino group of its respective Gly193. The remainder of the (SeO₄^2? ions are at lower occupancies and not nearly as definite. These are located around the surface of the enzyme where they generally interact with a positive charge and/or enter into hydrogen bonding with the enzyme. In general, the (SO₄^2? ions display relatively poor local 2-fold symmetry, probably because of their weak interaction with the enzyme.     

Activation of the sodium/hydrogen exchanger via the fibronectin-integrin pathway results in hematopoietic stimulation

The proliferative response of hematopoietic cells is regulated by many factors, including the presence and type of growth factors, the cellular microenvironment, and the physiochemical conditions prevailing in the tissue milieu. A process fundamental to all cells is the regulation of the intracellular acid-base conditions. One of the mechanisms by which intracellular pH (pH_i) is regulated is through the sodium/hydrogen exchanger, a ubiquitous membrane protein which exploits the intra- and extracellular sodium ion gradient to drive hydrogen ions out of the cell. However, activation of the exchanger via mitogenic and nonmitogenic signals leads to an increase in pH_i which, in turn, may directly or indirectly result in a proliferative response. It has been shown that interaction of fibronectin with its integrin receptor subunits α₄ and α₅ can result in activation of the Na⁺/H⁺ exchanger. In this report, we demonstrate that when mouse bone marrow cells are physically brought together in a preculture system we designate as high cell density culture (HCDC), in a small volume and at the same cellularity as that in the marrow, hematopoietic stem and progenitor cell populations are stimulated with no additional stimulation in the presence of growth factors. Neutralizing antibodies to the growth factors added to HCDC had little, if any, effect on the degree of stimulation. However, when antibodies to fibronectin or the α₄ integrin subunit were added to HCDC, inhibition was observed, indicating that the observed hematopoietic stimulation occurred via the fibronectin-integrin pathway. Addition of 5 μM 5-(N,N-hexamethylene) amiloride (5-HMA), a specific inhibitor of the Na⁺/H⁺ exchanger, also resulted in inhibition of in vitro hematopoiesis. Since the exchanger was implicated, we then measured the pH_i of normal and HCDC-treated bone marrow cells in the absence and presence of 5-HMA by flow cytometry using the fluorescent pH-sensitive indicator, carboxy SNARF-1 AM. It was found that cells subjected to HCDC exhibited a higher pH_i than normal fresh cells. In each case, the pH_i was lowered in the presence of 5-HMA. Furthermore, addition of antibodies to fibronectin or the α₄ integrin subunit to HCDC also reduced the pH_i to a similar level to that found for 5-HMA. Our results demonstrate, for the first time, that a hematopoietic stem and progenitor cell proliferative response can be initiated by activation of the Na⁺/H⁺ exchanger, leading to an increase in pH_i, via cell-cell interaction through the fibronectin-integrin pathway. This pathway could, therefore, be significant not only in normal hematopoietic regulation, but also under pathophysiological conditions. J. Cell. Physiol. 177:109–122, 1998. © 1998 Wiley-Liss, Inc.     

Preferential intracellular pH regulation represents a general pattern of pH homeostasis during acid–base disturbances in the armoured catfish,Pterygoplichthys pardalis

Preferential intracellular pH (pH_i) regulation, where pH_i is tightly regulated in the face of a blood acidosis, has been observed in a few species of fish, but only during elevated blood PCO₂. To determine whether preferential pH_i regulation may represent a general pattern for acid–base regulation during other pH disturbances we challenged the armoured catfish, Pterygoplichthys pardalis, with anoxia and exhaustive exercise, to induce a metabolic acidosis, and bicarbonate injections to induce a metabolic alkalosis. Fish were terminally sampled 2–3 h following the respective treatments and extracellular blood pH, pH_i of red blood cells (RBC), brain, heart, liver and white muscle, and plasma lactate and total CO₂ were measured. All treatments resulted in significant changes in extracellular pH and RBC pH_i that likely cover a large portion of the pH tolerance limits of this species (pH 7.15–7.86). In all tissues other than RBC, pH_i remained tightly regulated and did not differ significantly from control values, with the exception of a decrease in white muscle pH_i after anoxia and an increase in liver pH_i following a metabolic alkalosis. Thus preferential pH_i regulation appears to be a general pattern for acid–base homeostasis in the armoured catfish and may be a common response in Amazonian fishes.     

Day-to-night variations of cytoplasmic pH in a crassulacean acid metabolism plant

Summary In crassulacean acid metabolism (CAM) large amounts of malic acid are redistributed between vacuole and cytoplasm in the course of night-to-day transitions. The corresponding changes of the cytoplasmic pH (pH_cyt) were monitored in mesophyll protoplasts from the CAM plantKalanchoe daigremontiana Hamet et Perrier by ratiometric fluorimetry with the fluorescent dye 2′,7′-bis-(2-carboxyethyl)-5-(and-6-)carboxyfluorescein as a pH_cyt indicator. At the beginning of the light phase, pH_cyt was slightly alkaline (about 7.5). It dropped during midday by about 0.3 pH units before recovering again in the late-day-to-early-dark phase. In the physiological context the variation in pH_cyt may be a component of CAM regulation. Due to its pH sensitivity, phosphoenolpyruvate carboxylase appears as a likely target enzyme. From monitoring ΔpH_cyt in response to loading the cytoplasm with the weak acid salt K-acetate a cytoplasmic H⁺-buffer capacity in the order of 65 mM H+ per pH unit was estimated at a pH_cyt of about 7.5. With this value, an acid load of the cytoplasm by about 10 mM malic acid can be estimated as the cause of the observed drop in pH_cyt. A diurnal oscillation in pH_cyt and a quantitatively similar cytoplasmic malic acid is predicted from an established mathematical model which allows simulation of the CAM dynamics. The similarity of model predictions and experimental data supports the view put forward in this model that a phase transition of the tonoplast is an essential functional element in CAM dynamics.     

Effects of pH and Repellent Tactic Stimuli on Protein Methylation Levels in Escherichia coli

Intracellular pH (pH_int) and extracellular pH (pH_ext) of Escherichia coli were measured at 12-s time resolution by ³¹P-nuclear magnetic resonance: a sudden neutral-to-acid shift in pH_ext (e.g., from 7.0 to 5.6) caused a transient failure of homeostasis, with pH_int decreasing by about 0.4 unit in ca. 30 s and then returning to its original value (ca. 7.5) over a period of several minutes. Membrane proton conductance was estimated to be 20 pmol s⁻¹ cm⁻² pH unit⁻¹. Addition of the membrane-permeant weak acid benzoate at constant pH_ext also caused a lowering of pH_int; at high concentrations it generated an inverted transmembrane pH gradient (ΔpH). The buffering capacity of the cells was estimated by such experiments to be ca. 50 mM per pH unit. Effects of pH-related stimuli on the methyl-accepting chemotaxis proteins (MCPs) were examined: the steady-state methylation of MCP I was found to decrease when pH_int was lowered by weak acid addition or when pH_ext was lowered. The extent of demethylation in the latter case was too great to be explained by imperfect steady-state homeostasis; a small but reproducible undershoot in methylation level correlated with the observed short-term homeostatic failure. MCP II underwent smaller and more complex changes than MCP I, in response to pH-related stimuli. The methylation level of MCP I could not, by any condition tested, be driven below a limit of ca. 15% of the control level (unstimulated cells at pH_ext 7.0). The weak-acid concentration needed to reach that limit was dependent on pH_ext, as would be expected on the basis of ΔpH-driven concentrative effects. The potency ranking of weak acids was the same with respect to lowering pH_int, demethylating MCP I, and causing repellent behavioral responses. The data are consistent with a model whereby MCP I and hence tactic behavior are sensitive to both pH_int and pH_ext. Evidence is presented that pH_int may also have a direct (non-MCP-related) effect on motor function. Comparison of methyl-³H- and ³⁵S-labeled MCP I revealed that in both unstimulated and repellent-stimulated cells the major species did not carry methyl label, yet it had an electrophoretic mobility that indicated that it was more positively charged than the unmethylated form observed in methyltransferase mutants, and it was susceptible to base hydrolysis. This suggests that a substantial fraction of MCP I molecules is methylated or otherwise modified but neither exchanges methyl label nor undergoes reverse modification by repellent stimuli.     

Convenient Model To Describe the Combined Effects of Temperature and pH on Microbial Growth

A new model in which the maximum microbial specific growth rate ((mu)(infmax)) is described as a function of pH and temperature is presented. The seven parameters of this model are the three cardinal pH parameters (the pH below which no growth occurs, the pH above which no growth occurs, and the pH at which the (mu)(infmax) is optimal), the three cardinal temperature parameters (the temperature below which no growth occurs, the temperature above which no growth occurs, and the temperature at which the (mu)(infmax) is optimal), and the specific growth rate at the optimum temperature and optimum pH. The model is a combination of the cardinal temperature model with inflection and the cardinal pH model (CPM). The CPM was compared with the models of Wijtzes et al. and Zwietering et al. by using previously published data sets. The models were compared on the basis of the usual criteria (simplicity, biological significance and minimum number of parameters, applicability, quality of fit, minimum structural correlations, and ease of initial parameter estimation), and our results justified the choice of the CPM. Our combined model was constructed by using the hypothesis that the temperature and pH effects on the (mu)(infmax) are independent. An analysis of this new model with an Escherichia coli O157:H7 data set showed that there was a good correspondence between observed and calculated (mu)(infmax) values. The potential and convenience of the model are discussed.     

An increase in the intracellular pH of fertilized eggs of Xenopus laevis is associated with inhibition of protein and DNA syntheses and followed by an arrest of embryonic development

In many systems, events participating in cell division are controlled by intracellular pH (pH_i). In Xenopus eggs, fertilization is accompanied by an increase in pH_i which occurs concomitantly with an increase in protein synthesis and a reinitiation of DNA synthesis, leading the embryo to cell division. In this paper, we have shown that increasing pH_i of fertilized eggs from 7.8 to 8.2 by using weak bases produced an arrest in embryonic development. Such a change in pH_i was accompanied by a severe inhibition of both protein and DNA syntheses. In order to discriminate between a direct effect of pH_i and a pH-independent effect of weak bases on these biosyntheses, the situation was studied in vitro. For this purpose, cytoplasmic extracts were used in which weak base addition did not produce any change in pH. Under these conditions, protein synthesis was not inhibited, suggesting that pH is probably one of the events implicated in the regulation of protein synthesis. On the other hand, DNA synthesis was inhibited by weak bases in vitro, without any change in pH intervening.     

Energetic and regulatory role of proton potential in chloroplasts

The review focuses on the energetic and regulatory role of proton potential in the activity of chloroplasts, the light energy-converting organelles of plant cells. Mechanisms of generation of the transmembrane difference of electrochemical potentials of hydrogen ions in the chloroplast thylakoid membranes are considered. Methods for measuring the intrathylakoid pH in chloroplasts are described. It is shown that under conditions of phosphorylation in chloroplasts, the pH of the intrathylakoid space decreases moderately (pH_in ⩾ 6.0–6.2, at the stroma pH_out ∼ 7.8–8.0), with a corresponding concentration component of equal to ΔpH ⩽ 1.6–2.0. On analyzing the energy and structural features of ATP synthase of chloroplasts, we conclude that the energy stored as the concentration component of the proton potential ΔpH is sufficient to sustain ATP synthesis. The mechanisms of pH-dependent regulation of electron transport in chloroplasts (photosynthetic control of electron transport, enhancement of non-photochemical quenching of chlorophyll excitation in the light-harvesting antenna, light-induced activation of the Calvin-Benson cycle reactions, activation of ATP synthase) are considered briefly.     

Scavenging Rhodamine B dye using moringa oleifera seed pod

Moringa oliferia seed pod was modified using orthophosphoric acid (H₃PO₄) and used as adsorbent for sequestering Rhodamine B (Rh-B) dye from aqueous solution. The acid-modified adsorbent (MOSPAC) was characterized using Scanning Electron microscopy (SEM), Fourier Transform Infra Red (FTIR), Energy Dispersive X-ray (EDX), pH point of zero charge (pH_pzc) and Boehm Titration (BT) techniques, respectively. Operational parameters such as contact time, initial dye concentration, adsorbent dosage, pH and solution temperature were studied in batch process. Optimum dye adsorption was observed at pH 3.01. Equilibrium adsorption data was tested data using four different isotherm models: Langmuir, Freundlich, Temkin and Dubinin-Radushkevich. Langmuir isotherm model fitted most with maximum monolayer adsorption capacity of 1250 mg g^–1. Pseudo-second-order kinetic model provided the best correlation for the experimental data. Thermodynamic study showed that the process is endothermic, spontaneous and feasible. MOSPAC is an effective adsorbent for the removal of RhB dye from aqueous solutions.     

Intracellular pH of baker’s yeast

The distribution of bromophenol blue between the cell and the medium was used to calculate the intracellular pH of yeast. In buffered media the intracellular pH exhibited a plateau at pH _i =5.8 for low external pH values and another at pH _i =7.6 for high external pH values. The production of H ions by the yeast during utilization of glucose is not accompanied by an alkalinization of the cell interior. The pH _i even decreases somewhat in the presence of glucose and K ions.

1. (1)
   Внутриклеточный pH дрожжей вычисляли на основании распределения бромфеноловой сини между клетками и средой.