Growth response of axenic Entamoeba histolytica to hydrogen, carbon dioxide, and oxygen.

Entamoeba histolytica required CO2 for growth in axenic culture while growth was inhibited by H2. The organism was tolerant to 5% O2 in the gas phase and it was able to detoxify products of O2 reduction in the medium. The ameba did not require a negative oxidation-reduction potential for axenic growth. However, little or no free O2 was present in media exposed to 5% O2 in the gas phase. Growth was improved by adding yeast extract to the medium.     

Cell Size,Macromolecular Composition,and O2 Consumption During Agitated Cultivation of Naegleria gruberi*

SYNOPSIS. Cell size, macromolecular composition, carbohydrate utilization patterns, and O₂ concentrations were measured throughout the growth stages of Naegleria gruberi in agitated cultures in a complex medium. Biphasic logarithmic growth occurred during the initial 83 hr of growth and the mean generation time was 7.0 hr and 19 hr during initial and secondary log growth stages, respectively. The maximum yield was 5 × 10* amebaeJml. The pH rose rapidly (1 pH unit) during the secondary log growth phase (52-83 hr) and continued into the stationary growth phase (83-120 hr). Dry weight, total protein, carbohydrate, and RNA per ameba increased just before the secondary log growth phase. RNA increased 31% to 35% per ameba at the end of each phase of log growth. DNA increased ～ 2-fold throughout the different growth phases. Average cell size increased 90% during biphasic log growth then decreased during stationary phase. O₂ tension decreased from 100% to 18% of saturation during the biphasic growth phase, then increased during stationary growth to near 100% saturation. Glucose and total carbohydrate assays showed little utilization of those substrates throughout the growth stages. Naegleria gruberi presumably has a predominantly aerobic metabolism, also its metabolism may change during the different growth phases.     

A new principle of cell cultivation: No air-liquid interface but gas exchange across a synthetic membrane

Summary A completely liquid-filled growth chamber for axenic cultures ofTetrahymena pyriformis is described; gas exchange is ensured across a synthetic membrane. The chamber may be incorporated into a continuous flow system with inoculation and removal of cell samples under sterile conditions. Initially, the generation time of the cells was slightly prolonged, about 10%, but after some cell doublings decreased to 5%. The capacity of the cells to form food vacuoles (endocytosis) was unaltered during growth in the chamber. The synthetic membrane was highly permeable to O₂ and CO₂; however, cells grown in the chamber contained small refractive granules. The culture chamber permits the culture volume to be varied and it may be used for other protozoa, bacteria, and even tissue culture cells.     

Influence of oxygen on sulfate reduction and growth of sulfate-reducing bacteria

The ambivalent relations of sulfate-reducing bacteria to molecular O₂ have been studied with ten freshwater and marine strains. Generally, O₂ was reduced prior to sulfur compounds and suppressed the reduction of sulfate, sulfite or thiosulfate to sulfide. Three strains slowly formed sulfide at O₂ concentrations of below 15 M (6% air saturation). In homogeneously aerated cultures, two out of seven strains tested, Desulfovibrio desulfuricans and Desulfobacterium autotrophicum, revealed weak growth with O₂ as electron acceptor (up to one doubling of protein). However, O₂ was concomitantly toxic. Depending on its concentration cell viability and motility decreased with time. In artificial oxygen-sulfide gradients with sulfide-containing agar medium and also in sulfide-free agar medium under an oxygen-containing gas phase, sulfate reducers grew in bands close to the oxic/anoxic interface. The specific O₂ tolerance and respiration capacity of different strains led to characteristically stratified gradients. The maximum O₂ concentration at the surface of a bacterial band (determined by means of microelectrodes) was 9 M. The specific rates of O₂ uptake per cell were in the same order of magnitude as the sulfate reduction rates in pure cultures. The bacteria stabilized the gradients, which were rapidly oxidized in the absence of cells or after killing the cells by formaldehyde. The motile strain Desulfovibrio desulfuricans CSN slowly migrated in the gradients in response to changing O₂ concentrations in the gas phase.     

Modulation of epithelial cell proliferation in culture by dissolved oxygen

Modulation of epithelial cell proliferation by the dissolved oxygen concentration (P_O2) of the growth medium was assessed with primary human foreskin epithelium and a continuous monkey kidney epithelial cell line (LLC-MK₂). Direct measurement of the growth medium P_O2 provides the first quantitative evaluation of epithelial cell proliferation as a function of P_O2 provides the first quantitative evaluation of epithelial cell proliferation as a function of P_O2. Sustained proliferation of LLC-MK₂ cells occurs in serum-free medium equilibrated with a gas phase containing 18% or 30% O₂ v/v. Mid-logarithmic phase cultures rapidly consume dissolved oxygen; this results in a 60–70 mm Hg decline in P_O2 and leads to a stable growth medium P_O2 between 70 and 100 mm Hg, well above anoxic values. In contrast, if culture medium is equilibrated with a gas phase containing 0% or 1% O₂ v/v to yield a growth medium P_O2 ～ 20–40 mm Hg, proliferation of LLC-MK₂ and primary foreskin epithelial cells is retarded, and LLC-MK₂ cells use little dissolved oxygen. Gentle, continuous rocking to prevent diffusion gradient formation enhances proliferation slightly at the higher P_O2, but neither periodic fluid renewals nor continued rocking stimulates cells retarded by a lowered oxygen concentration to resume proliferation. The data collectively demonstrate that epithelial cell proliferation requires a P_O2 > 40 mm Hg, and threshold requirements are probably closer to 70 mm Hg. Glycolysis continues at a P_O2 insufficient for proliferation, but more lactic acid accumulates in actively proliferating cultures than in cultures equilibrated with 0% oxygen. We conclude that epithelial cells in vitro both consume more oxygen and require a higher P_O2 for continued proliferation, and that the oxygen requirement for epithelial cell proliferation exceeds that of a comparable population of fibroblasts for which low oxygen may enhance survival and proliferation.     

Measurement of the photorespiratory activity of the submerged aquatic plant Myriophyllum spicatum L.

Abstract The CO₂ compensation concentrations (points) of leaves of the submerged vascular aquatic plant Myriophyllum spicatum L. were determined in a closed aqueous system at pH 7.0 by a gas chromatographic technique and over the range 10–30deg;C were found to range from 36 to 46 cm³m^?3 in medium equilibrated with 21% O₂ (0.03 kgm^?3), and 25 to 35 cm³m^?3 in medium equilibrated with 2% O₂ (0.03 kgm^?3). The rates of true (TPS) and apparent (APS) photosynthesis of leaves were measured in medium equilibrated with 21% O₂ and buffered at pH 7.0, at subsaturating concentrations (12.8–18.8 mmol m^?3) of dissolved inorganic carbor. (DIC) containing H¹⁴CO₃, by determining the initial rates of uptake by the leaves of DIC and ¹⁴C-activity from the medium. The rate of photorespiration, the difference between TPS and APS, was 7.0–13.3% of TPS over the range of 10–25°C and rose to 29% of TPS at 35°C. The magnitude of the compensation point of this plant is therefore similar to, but is much less O₂-sensitive than, those of C₃ plants, and the photorespiratory rate, at DIC concentrations near the CO₂ compensation point, is very low compared to that of C₃ plants.     

Catabolic Activities of Neisseria meningitidis: Utilization of Succinate

Two strains of Saccharomycopsis guttulata, JB-1 and JB-3, isolated from stomach contents of domestic rabbits, were grown under different gas phases, and their growth rates were compared. Strain JB-1 grew exponentially at a maximal growth rate under a continuous gas phase of 15% CO₂, 2% O₂ in nitrogen. High cell yields with low cell granulation were obtained. The growth rates were almost the same between oxygen concentrations of 0.25 and 20% at 15% CO₂. Poor growth and early cell granulation occurred in the absence of oxygen at 15% CO₂. Growth increased at 2% O₂ in direct proportion to the carbon dioxide concentration up to 10 to 15% CO₂. A very high carbon dioxide content (e.g. 98%) was somewhat inhibitory. Cell granulation always occurred during the maximal stationary phase in media at pH 4, but was relatively slight at pH 5.6 or higher. Strain JB-3 responded to various gas phases in a similar manner except that it grew slowly in the absence of oxygen at 15% CO₂ (pH 4). The effect of an optimal gas phase on the growth of strain JB-1 was examined in relation to other environmental conditions. In the presence of 15% CO₂, 2% O₂, this strain grew exponentially in yeast autolysate-Proteose Peptone-glucose medium at 37 C at pH 2, 4, and 5.6 at approximately the same rate; the growth rate was somewhat lower at pH 6.2. Under similar conditions, strain JB-1 grew at 30 C and pH 4 at one-sixth its maximal growth rate. Cell granulation was greatly reduced at this temperature. With adequate CO₂ strain JB-1 also grew at a reduced rate in a yeast autolysate medium previously reported not to support growth. Results indicate that continuous gassing with an optimal gas phase increases the growth rate to the extent that the growth rate surpasses the death rate by a significant margin; as a result, granulated cells can be avoided almost entirely in the log phase.     

Characteristics of nitrogen-fixingKlebsiella oxytoca isolated from wheat roots

Summary Of 45 fermentative gram negative bacterial isolates examined from wheat roots, three were capable of fixing atmospheric nitrogen as determined by the acetylene reduction technique and by protein contents of cells. A gram negative non-motile facultatively anaerobic bacterial strain capable of N₂ fixation was identified asKlebsiella oxytoca ZMK-2.Optimal growth and N₂ fixation occurred at pH 6.5. The optimum temperatures for growth under anaerobic conditions ranged between 30°–37°C. Acetylene reduction by intact cells was strikingly inhibited by 0.1 atm. or greater partial pressure of O₂. Furthermore, the accumulation of H₂ in the gas phase over cultures ofKlebsiella oxytoca ZMK-2 at partial pressures greater than 0.02 atm. resulted in a striking inhibition in the rate of C₂H₂ reduction. The addition of suspensions of eitherKlebsiella oxytoca ZMK-2 orAzotobacter vinelandii or a mixed culture of these two organisms to axenic cultures of wheat plants produced no significant increase in plant growth as measured by plant dry weight or nitrogen content of plants.     

Oxidative Stress and Antioxidant Cell Protection Systems in the Microaerophilic Bacterium Spirillum winogradskii

The influence of oxygen availability during cultivation on the biosynthetic processes and enzymatic activities in the microaerophilic bacterium Spirillum winogradskii D-427 was studied, and the roles played by different systems of the defense against oxidation stress were determined. The metabolic adjustments caused by transition from microaerobic (2% O₂) aerobic conditions (21% O₂ of the gas phase) were found to slow down constructive metabolism and increase synthesis of exopolysaccharides as a means of external protection of cells from excess oxygen. This resulted in a twofold decline of the growth yield coefficient. Even though the low activity of catalase is compensated for by a multifold increase in the activities of other cytoplasmic enzymes that defend against toxic forms of O₂—peroxidase and enzymes of the redox system of glutathione (glutathione peroxidase and glutathione reductase)—massive lysis of cells starts in the midexponential phase and leads to culture death in the stationary phase because of H₂O₂ accumulation in the periplasm (up to 10 g/mg protein). The absence in cells of cytochrome-c-peroxidase, a periplasmic enzyme eliminating H₂O₂, was shown. It follows that the major cause of oxidative stress in cells is that active antioxidant defenses are located in the cytoplasm, whereas H₂O₂ accumulates in the periplasm due to the lack of cytochrome-c-peroxidase. The addition to the medium of thiosulfate promotes elimination of H₂O₂, stops cell lysis under aerobic conditions, lends stability to cultures, and results in a threefold increase in the growth yield.     

Sensitivity of chickpea and faba bean to root‐zone hypoxia,elevated ethylene,and carbon dioxide

During soil waterlogging, plants experience O₂ deficits, elevated ethylene, and high CO₂ in the root‐zone. The effects on chickpea (Cicer arietinum L.) and faba bean (Vicia faba L.) of ethylene (2 μL L^?1), CO₂ (2–20% v/v) or deoxygenated stagnant solution were evaluated. Ethylene and high CO₂ reduced root growth of both species, but O₂ deficiency had the most damaging effect and especially so for chickpea. Chickpea suffered root tip death when in deoxygenated stagnant solution. High CO₂ inhibited root respiration and reduced growth, whereas sugars accumulated in root tips, of both species. Gas‐filled porosity of the basal portion of the primary root of faba bean (23%, v/v) was greater than for chickpea (10%), and internal O₂ movement was more prominent in faba bean when in an O₂‐free medium. Ethylene treatment increased the porosity of roots. The damaging effects of low O₂, such as death of root tips, resulted in poor recovery of root growth upon reaeration. In conclusion, ethylene and high CO₂ partially inhibited root extension in both species, but low O₂ in deoxygenated stagnant solution had the most damaging effect, even causing death of root tips in chickpea, which was more sensitive to the low O₂ condition than faba bean.     

RESPONSES OF THE ACIDOPHILIC ALGA EUGLENA MUTABILIS (EUGLENOPHYCEAE) TO CARBON ENRICHMENT AT pH 31

A defined medium (MAM) simulating acid mine drainage waters was developed which supported reproducible growth rates of three axenic strains of Euglena mutabilis Schmitz. Growth responses to various pHs and carbon sources were examined under defined culture conditions. A lab strain and two 5eld isolates, tested over pH range 1.5-9.0, grew best under acidic conditions (pH < 5.5) with highest growth rates at pH 3-4. Photoauxotrophic growth rates of all strains at pH 3 were improved significantly over unstirred batch controls by bubbling with air and even more by enrichment with 5% CO₂ in air. These results confirmed inorganic carbon limitation in batch culture. Organic carbon substrates were tested as possible carbon supplements in batch culture at pH 3. None of the strains survived in the dark on any of the twenty organic sources added. In the light, the lab strain exhibited some photoheterotrophic growth potential on glucose, sucrose, ethanol, and amino acids but growth was inhibited by acetate. Field strains showed little or no growth improvement with any organic substrate addition. Under simultaneous enrichment with acetate and 5% CO₂ acetate continued to be inhibitory. Simultaneous enrichment with glucose and 5% CO₂ gave higher yields of the lab strain than with CO₂ alone but did not enhance growth of the field strain. We conclude that E. mutabilis is an acidophilic photoauxotroph which appears unable to use organic carbon supplements for growth even under conditions of carbon limitation.     

On-line estimation of O<Subscript>2</Subscript> production,CO<Subscript>2</Subscript> uptake,and growth kinetics of microalgal cultures in a gas-tight photobioreactor

Growth of the green algae Chlamydomonas reinhardtii and Chlorella sp. in batch cultures was investigated in a novel gas-tight photobioreactor, in which CO₂, H₂, and N₂ were titrated into the gas phase to control medium pH, dissolved oxygen partial pressure, and headspace pressure, respectively. The exit gas from the reactor was circulated through a loop of tubing and re-introduced into the culture. CO₂ uptake was estimated from the addition of CO₂ as acidic titrant and O₂ evolution was estimated from titration by H₂, which was used to reduce O₂ over a Pd catalyst. The photosynthetic quotient, PQ, was estimated as the ratio between O₂ evolution and CO₂ up-take rates. NH₄ ⁺, NO₂ ⁻, or NO₃ ⁻ was the final cell density limiting nutrient. Cultures of both algae were, in general, characterised by a nitrogen sufficient growth phase followed by a nitrogen depleted phase in which starch was the major product. The estimated PQ values were dependent on the level of oxidation of the nitrogen source. The PQ was 1 with NH₄ ⁺ as the nitrogen source and 1.3 when NO₃ ⁻ was the nitrogen source. In cultures grown on all nitrogen sources, the PQ value approached 1 when the nitrogen source was depleted and starch synthesis became dominant, to further increase towards 1.3 over a period of 3–4 days. This latter increase in PQ, which was indicative of production of reduced compounds like lipids, correlated with a simultaneous increase in the degree of reduction of the biomass. When using the titrations of CO₂ and H₂ into the reactor headspace to estimate the up-take of CO₂, the production of O₂, and the PQ, the rate of biomass production could be followed, the stoichiometrical composition of the produced algal biomass could be estimated, and different growth phases could be identified.     

Effect of oxygen on substrate utilization for nitrogen fixation and growth in Frankia spp.

Frankia, the actinomycete partner in the nitrogenfixing symbiosis of certain woody non-legumes, has been shown to fix nitrogen in pure culture under aerobic conditions. The sensitivity of in vivo nitrogen-fixation (acetylene reduction) to oxygen tension in the gas phase was measured in short-term assays with two Frankia isolates designated ARI3 and CcI3. The carbon source utilized had an effect on the optimum O₂ concentration for acetylene reduction. Cells utilizing an organic acid, e.g., propionate or pyruvate had maximum nitrogenase activity at an oxygen concentration of 15 to 20%. In contrast, cells respiring a sugar, e.g., trehalose or glucose, or endogenous reserves (glycogen or trehalose) had maximum acetylene reduction activity at 5 to 10% in the gas phase. Oxygen uptake kinetics showed that respiration in vesicle-containing cells utilizing trehalose had a biphasic response to oxygen concentration with a diffusion limited component at oxygen concentrations of 20 M to more than 300 M. These results suggested that trehalose was oxidized in the vesicles as well as in the vegetative hyphae. Oxygen concentration also had an effect on the trehalose-supported growth of cells (non nitrogenfixing, [⁺NH₄Cl]). Cells grown with 5–10% O₂ in the gas phase had a doubling time approximately half those grown with 20% O₂ (atmospheric). Propionate-grown cells showed similar growth rates at the two oxygen tensions, and grew faster (almost 2x) than the trehalose cells at 5–10% O₂. Trehalose also supported approximately 40% lower rates of oxygen uptake than propionate in vesicle-containing cells.     

UNEXPECTED RESPONSE TO VITAMIN B12 OF DOMINANT CENTRIC DIATOMS FROM THE SPRING BLOOM IN THE GULF OF MAINE (NORTHEAST ATLANTIC OCEAN)1,2

Twelve clones (seven species) representative of centric diatoms dominant in the spring phytoplankton bloom in the Gulf of Maine were isolated and rendered axenic. Genera included were Thalassiosira, Porosira and Chaetoceros. Unlike most centric diatoms studied previously, none of these has an absolute requirement for vitamin B_12. However, B₁₂ (5 ng.l^-1) stimulated growth of most clones by eliminating or reducing the lag phase and increasing the growth rate. Bloom population densities developed 4–54 days earlier with B₁₂ present. Several clones grown with B₁₂ removed more than 80% of the vitamin from the medium. When grown in vitamin-free medium the cells put 0.01–0.7 ng.l^-1 B₁₂ into the medium. We conclude that vitamin B₁₂ is of ecological significance even though the requirement for it is not absolute.     

Purification and characterization of an H<Subscript>2</Subscript>O-forming NADH oxidase from <Emphasis Type="Italic">Clostridium aminovalericum</Emphasis>: existence of an oxygen-detoxifying enzyme in an obligate anaerobic bacteria

Clostridium aminovalericum, an obligate anaerobe, is unable to form colonies on PYD agar plates in the presence of 1% O₂. When grown anaerobically in PYD liquid medium, the strain can continue normal growth after the shift from anoxic (sparged with O₂-free N₂ carrier-gas) to microoxic (sparged with 3% O₂/97% N₂ mixed carrier-gas) growth conditions in the mid exponential phase (OD₆₆₀=1.0). When the strain grew under 3% O₂/97% N₂, the medium remains anoxic. Thirty minutes after beginning aeration with 3% O₂, the activity of NADH oxidase in cell-free extracts increased more than five-fold from the level before aeration. We purified NADH oxidase to determine the characteristics of this enzyme in an obligate anaerobe. The purified NADH oxidase dominated the NADH oxidase activity detected in cell-free extracts. The enzyme is a homotetramer composed of a subunit with a molecular mass of 45 kDa. The enzyme shows a spectrum typical of a flavoprotein, and flavin adenine dinucleotide (FAD) was identified as a cofactor. The final product of NADH oxidation was H₂O, and the estimated K_m for oxygen was 61.9 M. These data demonstrate that an O₂-response enzyme that is capable of detoxifying oxygen to water exists in C. aminovalericum.Abbreviations NRIC NODAI Research Institute-Culture Collection Center, Tokyo University of Agriculture, Tokyo, Japan - SDS-PAGE sodium dodecyl sulfate polyacrylamide gel electrophoresis - PMSF phenylmethylsulfonyl fluoride     

Effects of various partial pressures of oxygen and carbon dioxide on different stages of somatic embryogenesis in Picea abies

Effects of various partial pressures of oxygen (5, 20 and 45 kPa) and carbon dioxide (0.03 and 6 kPa) on initiation, proliferation and maturation of somatic embryos in Picea abies were studied. The pO₂ had a significant effect on the initiation of embryogenic tissue from mature zygotic embryos. However, the effect of pO₂ was dependent on the strength of the basal medium. Low pO₂ stimulated the formation of embryogenic tissue when the zygotic embryos were incubated on full strength medium, but was inhibitory when half-strength medium was used. Proliferation of embryogenic tissue was stimulated by higher partial pressures of both CO₂ and O₂. The effect of the gas phase on maturation of somatic embryos varied between different cell lines. However, there was a general tendency for 5 kPa O₂ and 6 kPa CO₂ to stimulate maturation.Abbreviations ABA abscisic acid - BA benzyladenine - 2,4-D 2,4-dichlorophenoxyacetic acid - ET embryogenic tissue     

The effect of oxygen partial pressure in bioreactors on cell proliferation and subsequent differentiation of somatic embryos of Cyclamen persicum

The effect of the relative oxygen partial pressure (pO₂) in bioreactors on cell proliferation and subsequent differentiation of somatic embryos from suspension cultures of Cyclamen persicum Mill. was investigated. The growth rate of cell line 3738-VIII in growth-regulator containing medium in bioreactors at 5% pO₂ was slightly reduced in comparison to 10% and 20% pO₂. Cultures growing at 40% pO₂ had a lower growth rate, a markedly reduced cell viability and showed a decrease of the medium pH to 3.5. Because a pH-control with a setpoint of 3.3 caused cell death within 4 days, it was assumed, that the reason for the poor cell proliferation and viability in the cultures at 40% pO₂ was an effect of medium acidification rather than of the high O₂ partial pressure. A significantly higher number of germinating embryos was obtained from the cultures grown at 40% pO₂ than from those grown in flasks or in bioreactors at 5%, 10% and 20% pO₂. These results were specific for cell line 3738-VIII. Another cell line, 3736-12, did not show marked differences in cell proliferation, viability, pH or subsequent regeneration of somatic embryos when grown at different O₂ partial pressures. This revised version was published online in June 2006 with corrections to the Cover Date.     

Effect of inorganic carbon on photoautotrophic growth of microalga Chlorococcum littorale

The growth rate of a highly CO₂‐tolerant green alga, Chlorococcum littorale, was investigated in semi‐batch cultures at a temperature of 22°C, a light intensity of 170 μmol‐photon m^?2 s^?1 and CO₂ concentrations ranging from 1 to 50% (v/v) at atmospheric pressure. In the experiments, solutions were bubbled with CO₂ and N₂ gas mixtures to adjust CO₂ concentrations to minimize the influence of O₂. Growth rate, which was defined in terms of a specific growth rate μ, decreased with increasing CO₂ concentration at the conditions studied. The inhibition of growth by CO₂ gas could be attributed to the concentration of inorganic carbon in the culture medium. A growth model is proposed where key assumptions are the formation of bicarbonate ion HCO as substrate for algal growth and equilibrium between CO₂ inhibitor. The proposed growth model based on the Monod equation agreed with the experimental data to within 5% and provides better correlation than the conventional inhibition model, especially in the high CO₂ concentration region. © 2009 American Institute of Chemical Engineers Biotechnol. Prog., 2009     

Culturing of stoneworts and submersed angiosperms with phosphate uptake exclusively from an artificial sediment

1. We aimed to demonstrate reproducible nutrition and growth of macrophytes in non‐axenic laboratory cultures preventing growth of phytoplankton and epiphytes. 2. Macrophyte shoot segments were planted in a mixture of commercial acid‐washed silica sand with crystalline tricalcium phosphate, and this artificial sediment was covered with a layer of pure silica sand. The liquid mineral media used did not contain phosphorus but were rich in all other nutrient elements. A CO₂ reservoir provided sustainable CO₂ supply to macrophyte cultures by gas diffusion through a polyethylene membrane. 3. Chara hispida, Chara tomentosa, Chara baltica, Elodea canadensis, Potamogeton pectinatus and Zanichellia palustris could be cultivated for long term without medium exchange and aeration. Microalgae growth was prevented by the absence of phosphate in the water column. Mobilisation of tricalcium phosphate and phosphate uptake by the rhizoids of C. hispida enabled sustainable rapid shoot growth and increased the concentration of inorganic phosphate in the shoot dry weight by five to six times in comparison with plants cultivated on pure silica sand. A significant growth support from tricalcium phosphate was also observed for E. canadensis, but the rate of phosphate uptake by the roots was not sufficient to maintain a storage pool of inorganic phosphate (P_i) in the growing shoots of this plant. 4. Membrane‐controlled CO₂ supply from a reservoir and artificial sediments like the one described provide attractive options for the laboratory culture of macrophytes.     

Characteristics of a nitrogen-fixing methanotroph,Methylocystis T-1

A methane-oxidizing bacterium capable of nitrogen fixation was isolated from soil taken from an area which leaked methane gas. Strain T-1 was a catalase and oxidase-positive, gram-negative straight rod-shaped strictly aerobic bacterium which formed lipid cysts and type II intracytoplasmic membranes. The organism was a microaerophilic nitrogen-fixing methanotroph. Strain T-1 is considered to be classified intoMethylocystis. The organism evolved hydrogen gas when grown in the nitrogen-free medium of atmospheric oxygen concentrations of 1.5% or more. Below this level, however, hydrogen gas was not evolved. In addition to methanol, formaldehyde and formate, ethanol, acetate and hydrogen gas served as oxidizable substrates for the acetylene reduction test. H₂-stimulated nitrogenase activity was limited in a very narrow range of oxygen concentration and not detected at 2% O₂. With acetate as the substrate, however, about an 80% of the maximum acetylene reduction activity was detected at 2% O₂. These results suggest that strain T-1 is capable of recycling the hydrogen gas evolved during nitrogen fixation under low partial pressures of O₂.