Conversions of Microbial Products in Relation to Oxygen Supply in Inosine Fermentation

On the basis of the ratio (cell’s respiration rate/maximum oxygen demand of cells, r_{a b}/K_rM) as a new criterion of oxygen supply, symptoms of oxygen deficiency was described in inosine fermentation. Conversions of the products were observed to occur in relation to the extent of oxygen deficiency. When oxygen demand of the cells was satisfied (r_{a b}/K_rM = 1.0), the cells accumulated exclusively inosine. Under limited oxygen supply at the value of r_{a b}/K_rM 0.5~0.9, on the other hand, inosine formation was inhibited and acetoin was the predominant product. When oxygen supply was limited more strictly at the value of r_{a b}/K_rM smaller than 0.3, the cells excreted 2,3-butyleneglycol as the main product.     

Simultaneous Measurement of Dissolved Oxygen and Oxidation-Reduction Potentials in the Aerobic Culture

The most dominant factor influencing the oxidation-reduction potentials (E) in the cultured system was oxygen tension. H was an useful index to express the degree of oxygen supply in place of dissolved oxygen (P_L) under a limited oxygen supply. The conversion of microbial products caused by the change in oxygen supply was clearly analyzed by the use of E value. Bacillus subtilis excreted lactic acid at the E value ?220 mV, 2,3-butyleneglycol at ?195 mV and acetoin at ?160mV as the main product. E also gave the significant information concerning the changes in cell’s respiration. Cyanide at the concentration of 10^?5m, azide at 10^?3m and 2,4-dinitrophenol (DNP) at 10^?2m inhibited cell respiration causing the decrease in E and the increase in P_L, and DNP at 0.4×10^?3m promoted oxygen uptake of the cells causing the decrease in both E and P_L.     

Spectral and functional characterization of membrane fragments from the facultative photosynthetic bacterium Rhodopseudomonas blastica

The cytochromes of photosynthetically grown Rhodopseudomonas blastica have been thermodynamically characterized using the technique of redox titrations. Six cytochromes were present; two cytochromes c, E _m7= +295mV, E _m7=+345mV; and four cytochromes b, E _m7=+290mV, E _m7=+130mV, E _m7=+60mV, E _m7=-4mV. These cytochromes were tightly bound except for cytochrome c with E _m7 of+345mV which was mostly present in the soluble cell extracts.The effects of cyanide on both the cytochrome c oxidase activity and the NADH-dependent respiration, revealed the presence of a branched respiratory chain, one branch leading to a cyanide-resistant oxidase containing pathway and the other including the cyanide-sensitive cytochrome c-oxidase.The effects of antimycin A, myxothiazol and 5-undecyl-6-hydroxy-4,7-dioxobenzothiazole (UHDBT) on the steadystate NADH-dependent respiration were also studied. Antimycin A and myxothiazol appeared to act at the level of the ubiquinol-cytochrome c oxidoreductase while UHDBT drastically affected both respiratory branches.Absorption spectra of chromatophore photopigments resulted to be similar to those reported in many species of facultative photosynthetic bacteria although carotenoid absorption maxima were blue-shifted by 5 nm.The light-induced oxygen reduction performed by chromatophores from R. blastica suggested a strict interaction between photosynthetic and respiratory apparatuses.     

Short-and long-term effects of cadmium on transmembrane electric potential (E m) in maize roots

In this study, the effects of Cd on root growth, respiration, and transmembrane electric potential (E _m) of the outer cortical cells in maize roots treated with various Cd concentrations (from 1 μM to 1 mM) for several hours to one week were studied. The E _m values of root cells ranged between −120 and −140 mV and after addition of Cd they were depolarized immediately. The depolarization was concentration-dependent reaching the value of diffusion potential (E _D) when the Cd concentration exceeded 100 μM. The values of E _D ranged between −65 to −68 mV (−66 ± 1.42 mV). The maximum depolarization of E _m was registered approx. 2.5 h after addition of Cd to the perfusion solution and in some cases, partial (Cd > 100 μM) or complete repolarization (Cd < 100 μM) was observed within 8–10 h of Cd treatment. In the time-dependent experiments (0 to 168 h) shortly after the maximum repolarization of E _m a continuous concentration-dependent decrease of E _m followed at all Cd concentrations. Depolarization of E _m was accompanied by both increased electrolyte leakage and inhibition of respiration, especially in the range of 50 μM to 1 mM Cd, with the exception of root cells treated with 1 and 10 μM Cd for 24 and 48 h. Time course analysis of Cd impact on root respiration revealed that at higher Cd concentrations (> 50 μM) the respiration gradually declined (∼ 6 h) and then remained at this lowest level for up to 24 h. All the Cd concentrations used in this experiment induced significant inhibition of root elongation and concentrations higher than 100 μM stopped the root growth within the first day of Cd treatment. Our results suggest that Cd does not cause irreversible changes in the electrogenic plasma membrane H⁺ ATPase because fusicoccin, an H⁺ ATPase activator diminished the depolarizing effect of Cd on the E _m. The depolarization of E _m in the outer cortical cells of maize roots was the result of a cumulative effect of Cd on ATP supply, plasmalemma permeability, and activity of H⁺ ATPase.     

Effect of repeated exercise fatigue on the swimming performance of juvenile rock carp (Procypris rabaudi,Tchang)

The swimming performance of juvenile rock carp (Procypris rabaudi, Tchang) subjected to repeated fatigue exercise was studied using a flume-type respirometer at 20°C. The critical swimming speed (U_crit) and oxygen consumption rate (MO₂) of juvenile rock carp were measured during two successive stepped velocity tests, following a 60 min rest interval. U_crit of rock carp was giving a recovery ratio (R_r) of 92.64%, and exertion exercise decreases U_crit. When MO₂ was plotted as a linear function of U, the slope for trial 1 was 1.06 and 1.50 for trial 2, indicating a decreasing in swimming efficiency. The maximum metabolic rate (MMR) increased from 17.06 ± 1.14 mmol O₂/(kg·hr) to 19.14 ± 1.23 mmol O₂/(kg·hr), and the exercise post oxygen consumption rate (EPOC) increased from 9.00 to 9.65 mmol O₂/kg. Repeated fatiguing exercise increased both the aerobic and anaerobic cost of reaching U_crit, but anaerobic metabolism accounted for a larger proportion in the trial 2. The data investigation on the swimming performance and the physiological response to fatigue provide important design criteria for fishways.     

Respiration and oxygen transport in soybean nodules

Summary The respiration rate of individual soybean (Glycine max Merr.) nodules was measured as a function of pO₂ and temperature. At 23°, as the pO₂ was increased from 0.1 to 0.9 atm, there was a linear increase in respiration rate. At 13°, similar results were obtained, except that there was an abrupt saturation of respiration at approximately 0.5 atm pO₂. When measurements were made on the same nodule, the rate of increase in respiration with pO₂ was the same at 13° and 23°. Additional results were that 5% CO in the gas phase had no effect on respiration, except for a small decrease in the pO₂ at which respiration became saturated. Also, nodules still attached to the soybean root displayed the same respiratory behavior as detached nodules. A model for oxygen transport in the nodule is presented which explains these results quantitatively. The essence of the model is that the respiration rate of the central tissue of the nodule is almost entirely determined by the rate of oxygen diffusion to the respiratory enzymes. Evidence is given that the nodule cortex is the site of almost all of the resistance to oxygen diffusion within the nodule.     

The Critical Oxygen Pressures for Respiration in Intact Plants

Two methods for determining critical respiratory oxygen pressure in whole plants are described. By a polarographic method involving the use of cylindrical platinum electrodes the following critical oxygen pressures for root respiration were found: Rice (cv. Norin 36). 0.024 atm: Rice (cv. Norm 37). 0.026 atm: Eriophorum angustifolium. 0.02 atm. These values contrast markedly with those obtained in vitro, and support earlier criticisms of in vitro measurements: they call into question the use of such data in the modelling of root aeration. When the results were assessed by an electrical analogue system, it was concluded that the respiratory activity in the intact root does not follow the normally accepted hyperbolic relationship with oxygen partial pressure. The experimental data were simulated most closely by assuming the critical oxygen pressure to be a function of respiratory responses in the low porosity (high diffusional impedance) tissues of the root meristem and stele, and respiratory activity in the moderately porous root cortex to be unaffected at values greater than 0.001 atm. A critical oxygen pressure of 0.025–0.04 atm for E. angustifolium was found from analyses of the gas phase oxygen in the leaves of whole plants after submergence in the dark. It was concluded that the higher value found by this method was most likely a function of respiratory responses in root tissue remote from the leaf and should not be regarded as the critical oxygen pressure for leaf respiration. The form of the oxygen concentration vs. time plot again suggested a very much lower critical oxygen pressure for certain of the plant tissues.     

CO2 and water vapour exchange through adaxial and abaxial surfaces of tobacco leaves of different insertion level

CO₂ uptake (P _N ) and water vapour efflux (E) through adaxial and abaxial surfaces were measured separately and the corresponding diffusive resistances for water vapour (r ₁) were calculated in leaves of different insertion levels during vegetative growth of tobacco plants. Relatively higher values of the abaxialP _N/E ratio in comparison with the adaxial one were found in agreement with relatively higherE _ad/E _ab coefficients and the distribution of the gas exchange in plants in all measurements carried out. Because of the more rapid decrease of theP _N rates as compared with theE rates theP _N/E ratios of both surfaces decreased gradually from young to old leaves. The decreasing values ofE _ad/E _ab andP _N,ab/P _N,ab coefficients showed thatr _1,ab increased with the age of the leaves more quickly thanr _1,ab.     

Effect of photosynthetic biofilms on the open‐circuit potential of stainless steel

Periodic illumination of photosynthetic biofilms on AISI* 316L stainless steel resulted in evolution of oxygen (1–7 mg.1^‐1) and a corresponding increase in open circuit potential (E_corr) from 2 to 15 mV. The change in E^ depended on the interval of illumination. When the dark cycle began, elevation in potential was followed by an immediate drop. Illumination did not affect E_corr in sterile systems or in systems that contained only nonphotosynthetic eubacteria. Radiated heat from illumination accounted for changes of 4 to 5°C in temperature which, in the absence of oxygen production, should decrease dissolved oxygen by 0.75 mgl^‐1 and decrease E_corr by 1 mV. Positive shifts of E_corr induced by periodic illumination of photosynthetic biofilms are primarily the result of oxygen production.     

Hydrocarbon fermentation: Kinetics of microbial cell growth

Modeling of microbial growth using nonmiscible substrate is studied when kinetics of substrate dissolution is rate limiting. When the substrate concentration is low, the growth rate is described by an analytical relation that can be identified as a Contois relationship. If the substrate concentration is greater than a critical value S_crit, the potentially useful hydrocarbon S* concentration is described by S* = S_crit/(1 + S_crit/S). A relationship was found between S_crit and the biomass concentration X. When X increased, S_crit decreased. The cell growth rate is related to a relation μ = μ_m[A(X/S_crit)(1 + S_crit/S) + 1]^?1. This model describes the evolution of the growth rate when exponential or linear growth occurs, which is related to physico-chemical properties and hydrodynamic fermentation conditions. Experimental data to support the model are presented.     

Midday depression of tree root respiration in relation to leaf transpiration

The root respiration rate often shows an exponential or a linear relationship with temperature under laboratory conditions. However, under intact conditions in the field, the root respiration rates of some tree species decreased around midday despite an increment of the root temperature (Bekku et al. 2009). To clarify the cause of midday depression, we examined the relationships between the intact root respiration and parameters of leaf gas exchange through the simultaneous field measurement of the gas exchange in the leaf and root of Quercus crispula and Chamaecyparis obtusa, which are canopy trees. There were no significant relationships between the root respiration rates (R _r) and the parameters of leaf gas exchange in the field. However, in C. obtusa, the relationships between R _r and the transpiration rates (E) at 1 h before the measurement of R _r were fitted by logarithmic function with a determination coefficient of 0.60–0.89. In the light-manipulation experiments using saplings, R _r had significant positive correlations with E at 20 min before the measurement of R _r, root temperature (T _r), and the photosynthesis (P _n) at 20 min before the measurement of R _r. We examined which factor, P _n or E, affects the root respiration rate through a manipulation experiment using a growth chamber regulating the ambient CO₂ concentration and relative humidity independently under constant air temperature and photosynthetic photon flux density. As a result, the root respiration rates changed corresponding to E and not P _n. These results suggest that the root respiration rate of trees changes significantly in the daytime and is affected by the leaf transpiration rate as well as the temperature.     

The effects of oxygen levels on oxygen consumption, survival and ventilatory frequency of sharpsnout sea bream (Diplodus puntazzo Gmelin, 1789) at different conditions of temperature and fish weight

The respiratory behaviour of the sharpsnout sea bream (Diplodus puntazzo) with fish weights between 15 and 509 g at temperatures of 15–29°C was studied, with special attention paid to critical and lethal oxygen saturation (S_crit and LC₅₀, respectively) and ventilatory frequency (V_f). The species maintained a constant oxygen consumption rate regardless of the concentration of dissolved oxygen, until S_crit was reached. The mean of S_crit and LC₅₀ was 34% (2.4 mg L⁻¹) and 11% (0.8 mg L⁻¹), respectively. The S_crit was independent of fish weight and temperature, whereas the LC₅₀ values were positively correlated with both factors (P < 0.05). The higher resistance in small fish could be due to their greater V_f response to hypoxia than in larger animals. Furthermore, the increased metabolism resulting from the effect of temperature was offset by an increased V_f. The V_f remained constant down to a mean value of 67% oxygen saturation, regardless of fish weight and temperature. These findings suggest an optimum oxygen saturation of above 70% for D. puntazzo culture.     

Hypoxia tolerance decreases with body size in red drum Sciaenops ocellatus

Mass‐specific oxygen consumption rate, i.e. standard metabolic rate (R_s) and critical oxygen tension (P_crit) of red drum Sciaenops ocellatus were measured and scaled over a 2500‐fold range in mass (M_F; 0·26–686 g). R_s conformed to well established models (R_s = 3·73·91 M_F^?0·21; r² = 0·86) while P_crit increased over the size range (P_crit = 3·15 log₁₀M_F + 16·19; r² = 0·44). This relationship may be ecologically advantageous as it would allow smaller S. ocellatus to better utilize hypoxic zones as habitat and refuge from predators.     

Influence of soil porosity on water use in<Emphasis Type="Italic"> Pinus taeda</Emphasis>

We analyzed the hydraulic constraints imposed on water uptake from soils of different porosities in loblolly pine (Pinus taeda L.) by comparing genetically related and even-aged plantations growing in loam versus sand soil. Water use was evaluated relative to the maximum transpiration rate (E _crit) allowed by the soil-leaf continuum. We expected that trees on both soils would approach E _crit during drought. Trees in sand, however, should face greater drought limitation because of steeply declining hydraulic conductivity in sand at high soil water potential (Ψ _S). Transport considerations suggest that trees in sand should have higher root to leaf area ratios (A _R:A _L), less negative leaf xylem pressure (Ψ _L), and be more vulnerable to xylem cavitation than trees in loam. The A _R:A _L was greater in sand versus loam (9.8 vs 1.7, respectively). This adjustment maintained about 86% of the water extraction potential for both soils. Trees in sand were more deeply rooted (>1.9 m) than in loam (95% of roots <0.2 m), allowing them to shift water uptake to deeper layers during drought and avoid hydraulic failure. Midday Ψ _L was constant for days of high evaporative demand, but was less negative in sand (–1.6 MPa) versus loam (–2.1 MPa). Xylem was more vulnerable to cavitation in sand versus loam trees. Roots in both soils were more vulnerable than stems, and experienced the greatest predicted loss of conductivity during drought. Trees on both soils approached E _crit during drought, but at much higher Ψ _S in sand (<–0.4 MPa) than in loam (<–1.0 MPa). Results suggest considerable phenotypic plasticity in water use traits for P. taeda which are adaptive to differences in soil porosity. Received: 28 December 1999 / Accepted: 31 March 2000     

Nitrogen concentration of cauliflower organs as determined by organ size,N supply,and radiation environment

Data from field experiments carried out in three consecutive years under contrasting N supply and radiation environment altered by artificial shading were used to identify (a) the relationship between N concentration and organ size under conditions of unrestricted N supply and (b) critical levels of soil nitrate (Nmin_crit), where nitrogen concentration of cauliflower organs begin to decline because of N limitations. The decline of N concentrations in cauliflower was analysed at different levels of morphological aggregation, i.e., the whole shoot level, the organ level (leaves, stem, and curd), and within different leaf groups within the canopy. Nmin_crit values (0–60 cm soil depth) for total nitrogen concentration of cauliflower organs leaves, stem and curd were estimated at 85, 93 and 28 kg N ha^–1, respectively. Within the canopy, Nmin_crit values for total N of leaves increased from the top to the bottom from 44 to 188 kg N ha^–1. Nmin_crit values for protein N in leaves from different layers of the canopy were much lower at around 30 kg N ha^–1, without a gradient within the canopy. It is discussed that these differences in Nmin_crit values are most likely a consequence of N redistribution associated with nitrogen deficiency. The decline of average shoot nitrogen concentrations, [Nm] (%N DM), with shoot dry matter, W _sh, (t ha^–1) under conditions of optimal N supply was [Nm]= 4.84 (±0.071) W _sh ^{–0.089(± 0.011)}, r ²=0.67 (±S.E.). The reduction of radiation intensity by artificial shading (60% of control) had no significant influence on total nitrogen concentrations of leaves and only a small influence on protein nitrogen concentrations in lower layers of the canopy. The leaf nitrate nitrogen fraction of nitrogen, f _nitr (–), within the canopy decreased linearly with increased average incident irradiance in different canopy layers (I _av, W PAR m^–2) (f _Nitr. = 0.2456(±0.0188) – 0.0023(±0.0004)I _av, r ² = 0.67.     

Studies on the Ventilation in Submerged Fermentations

Quantitative studies on the dissolution and dissociation of carbon dioxide in a cultured system were made. The inosine fermentation and the glutamic acid fermentation were employed for this study. According to the results obtained in this experiment, the quantity of dissociated carbonic acid in cultured liquid was given by Henderson-Hasselbalch’s equation with experimental pK′. The method for the direct determination of bicarbonate ion concentration was also investigated. The Warburg direct method gave a satisfactory result for this purpose.

By using the modified Severinghaus CO₂ electrode, the relationship between partial pressure of carbon dioxide in effluent gas and that in culturing system was investigated. Partial pressure of carbon dioxide in gas phase was almost equivalent to the average value of dissolved carbon dioxide tension in liquid phase for a given short time of the fermentation. The term of r_e was introduced in order to study the dynamic characteristics of carbon dioxide evolution in submerged fermentors. The dynamic characteristics of respiration in submerged fermentation was also studied by using biological r_ab and r_e.     

Correlation of anaerobic biodegradability and the electrochemical characteristic of azo dyes

Some experiments were conducted to study some electrochemical factors affecting the bacterial reduction (cleavage) of azo dyes, knowledge of which will be useful in the wastewater treatments of azo dyes. A common mixed culture was used as a test organism and the reductions of Acid Yellow 4, 11, 17 and Acid Yellow BIS were studied. It was found that the azo dyes were reduced at different rates, which could be correlated with the reduction potential of the azo compounds in cyclic voltammetric experiments. Acid Yellow BIS (E _r − 616.75 mV) was reduced at the highest rate of 0.0284 mol g dry cell weight⁻¹ h⁻¹, Acid Yellow 11 (E _r − 593.25 mV) at 0.0245 mol g dry cell weight⁻¹ h⁻¹ and Acid Yellow 4 (E _r − 513 mV) at 0.0178 mol g dry cell weight⁻¹ h⁻¹. At the same time, the decolourization rate of Acid Yellow 17 (E _r − 627.5 mV) was 0.0238 mol g dry cell weight⁻¹ h⁻¹, which was affected by the nature of chlorine substituent. Reduction of these azo dyes did not occur under aeration conditions. These studies with a common mixed culture indicate that the reduction of azo dyes may be influenced by the chemical nature of the azo compound. The reduction potential is a preliminary tool to predict the decolourization capacity of oxidative and reductive biocatalysts.     

Respiratory activity of Candida tropicalis during growth on hexadecane and on glucose

Summary Rates of oxygen uptake and the oxygen demand during growth of Candida tropicalis on hexadecane and glucose were determined in batch experiments. Oxygen demand was 2.5 fold higher for the synthesis of one unit of cell mass from hydrocarbon than from glucose. On the other hand specific respiration is of the same order of magnitude for both substrates, e.g. 12 mmoles O₂xh^-1xg^-1 (dry weight) and seems to be a constant of this organism. Higher rates of oxygen supply into the medium had no effect on the specific rates of respiration. Specific growth rates on hexadecane were 2.4 times lower than on glucose. It is concluded, that rates of synthesis of cell components are controlled by the overall capacity of the respiratory pathways.     

Respiration of Senecio Shoots: Inhibition during Photosynthesis, Resistance to Cyanide and Relation to Growth and Maintenance

Respiration and dry matter producation were measured in shoots of senecia aquaticus Hill, which is flood tolerant and in shoots of S. jacobaea L., which is flood- sensitive. Both species were grown in culture solutions of high and of low oxygen concentration Growth of food of S. jacobaca was unaffected by a low oxygen supply bur growth of S. jacobaca was severly hampered by a low oxygen concentration in the root medium. Kinetic data about the rate of apparent photosynthesis at low oxygen conetration and different carbon dioxide concentrations indicated that at light saturation respiration was strongly repressed during photosynthesis. Shoot growth respiration, i.e. the amount of carbon dioxide produced for synthesis of shoot dry, matter appeared to be absent on S. jacobaea and to be very low (13.mg CO₂/g dry shoots) in S. aquaticus. In comparison with values prepiration rate was 2.8. 2.0. 1.5 and 1.3mg CO₂/h.g dry shoots in aerobically and anaerobically growth S. jacobaea and in aerobically and anaerobically growth S. aquabaea respectively. These values were also low in comprision with values previously found for roots of the same species. Shoot dark respiration on S. aquaticus was inbihitedd by a com bination on CN and salicylhydroxamic acid (SHAM), but not by application on one of these inhibitors alone. It was therefore concluded that an alternative oxidative pathway was present but not active in shoots of S. aquaticus. In the absence of inhibited of the cylochorome pathway. The low value of growth respiration and maintenance respiration rate in the shoots as compared with those in the roots of the investigated Sencio species are discussed in relation to the activity of the alternative oxidative pathway and to the possibilbity of a direct supply of ATP by photosynthesis intead of respiratory meta bolism.     

Changes in membrane potential during mouse egg development

The electrical membrane potential (E_m) was measured in the developing mouse egg with intracellular microelectrodes. The oocyte had a low negative E_m of ?8.3 ± 0.8 mV (mean ± SE) when immature, which decreased and reversed polarity to a small positive value (+1.9 ± 0.2 mV) in the mature ovulated oocyte. After fertilization E_m returned to a negative value (?9.2 ± 0.5 mV) similar in magnitude to that observed in immature oocytes and then increased significantly (P < 0.01) at both the two-cell (?10.7 ± 0.3 mV) and morula stage (?12.8 ± 0.7 mV) and leveled out at the blastocyst stage (?12.9 ± 0.7 mV). Average potential difference recorded across the blastocoele wall of not fully expanded blastocysts was ?5.0 ± 0.5 mV. These data represent the first report on membrane potentials of the mammalian egg during development. A striking similarity is seen in the relative changes in E_m throughout development of the mouse egg in comparison to those seen in other invertebrate and vertebrate eggs.