Regulation of exoprotease production by temperature and oxygen in Vibrio alginolyticus

The production of an extracellular collagenase and an alkaline protease by Vibrio alginolyticus during stationary phase was inhibited by a temperature shift from 30 to 37°C and by a lack of oxygen. The stability of the exoproteases was unaffected by incubation at 37°C and aeration. The optimum growth temperature for the V. alginolyticus strain was 33.5°C Aeration enhanced the rate of growth of exponential phase cells. Temperature and oxygen did not affect the growth of stationary phase cells when the exoproteases were being produced. Macromolecular synthesis in stationary phase cells was not affected by temperature. There was no rapid release of the exoproteases after temperature shift down and chloramphenicol inhibited the production of the enzymes when added at time of temperature shift down from 37 to 30°C. The regulation of exoprotease production by temperature and oxygen was specific and has implications regarding the ecology of V. alginolyticus. Cerulenin, quinacrine and O-phenanthroline inhibited the production of the exoproteases.     

Bioreactor studies on the effect of dissolved oxygen concentrations on growth and differentiation of carrot (Daucus carota L.) cell cultures

A bioreactor control system was used to investigate the effects of two dissolved oxygen concentrations (10% and 100%) on the growth and differentiation of Daucus carota L. cell cultures. The strategy used allowed the dissolved oxygen concentration to be controlled without the need for changing either the agitator speed or the total gas flow rate. During the proliferation phase, reducing oxygen resulted in a lower growth rate and in a delay in sugar uptake kinetics. Nonetheless, varying levels of oxygen were observed to have no effect on the final dry biomass. The higher alcohol dehydrogenase activity obtained under reduced oxygen conditions suggests that proliferating cultures adapted to the hypoxic environment by inducing alcoholic fermentation. Cell differentiation was highly sensitive to reduced oxygen since under this condition, the somatic embryo production was inhibited by about 75%. Sugar uptake and embryo formation were also delayed.Abbreviations ADH alcohol dehydrogenase - 2,4-D 2,4-dichlorophenoxyacetic acid - DO2 dissolved oxygen - SE somatic embryos - Tris tris(hydroxymethyl)-aminoethane     

The development of structure and function in chloroplasts of greening mutants of Scenedesmus I. Formation of chlorophyll

Several mutant strains of Scenedesmus obliquus have been isolatedwhich show only traces of chlorophyll when grown heterotrophicallybut, when transferred to light, develop chlorophyll in amountsequivalent to the wild-type strain. The action spectrum forgreening of one of these mutants, C-2A', while in a stationarygrowth phase, revealed a predominant influence of blue lightwith a maximum effectiveness around 460 nm; possible involvementof either carotenoids or flavoproteins in the greening responseis suggested. The greening process is absolutely dependent uponlight and oxygen and the kinetics demonstrate two distinctivephases. The initial phase is blue-light dependent and apparentlylinked energeticalty to the "respiratory" capacity of the cell,whereas the second one depends upon the increased photosyntheticcapacity resulting from the initial stage of chlorophyll production.Chlorophyll synthesis ceased completely when cultures were transferredto the dark but recommensed at the same rate when once againplaced in the light. The onset of greening is accompanied byan enhancement of respiration and of polysaccharide utilization.The rate of greening of C-2A' is markedly influenced by temperaturein the range of 20 to 30°C. Greening is prevented by anaerobicconditions, potassium cyanide, dinitrophenol, sodium arsenite,sodium fluoroacetate and sodium azide. Inhibition of the secondphase also results when photosynthesis is prevented, i.e., byDCMU inhibition or carbon dioxide exclusion. Possible mechanismsfor greening in this mutant are discussed. ¹ A portion of the results presented here was reported at the"International Seminar on Physiology of Differentiation in Plants",Simla, India, May 1971. (Received February 22, 1972; )     

Pressurized gas transport in two Japanese alder species in relation to their natural habitats

Oxygen uptake measurements have shown that pressurized gas transport, resulting from the physical effect of thermo-osmosis of gases, improves oxygen supply to the roots of the seedlings in two alder speciesAlnus japonica (Thunb.) Steud. andAlnus hirsuta (Spach) Rupr., which are both native in Japan. When gas transport conditions were established by irradiation of the tree stems the internal aeration was increased to a level nearly equal to the oxygen demand of the root system in leafless seedlings ofA. hirsuta, but was higher inA. japonica so that excess oxygen was excreted into the environment. An increase of superoxide dismutase (SOD) activity, which protects plants from toxic oxygen radicals and post-anoxic injury, has been observed in root tissues ofA. japonica when the seedlings were flooded for 3 days. The increase of SOD activity, in concert with high gas transport rates, may enable this tree species to grow in wet sites characterized by low oxygen partial pressure in the soil and by varying water tables. A less effective gas transport, flood-induced reduction of SOD activity in root tissues, and reduced height growth in waterlogged soil may be responsible for the fact thatA. hirsuta is unable to inhabit wettland sites.     

Effect of anoxic conditions on wood-decay fungi treated with argon or nitrogen

The effects of low-oxygen conditions, achieved with either argon or nitrogen gas, on the viability of wood-decay fungi Coniophora puteana and Antrodia vaillantii, grown on artificial growth medium, were tested. Initial tests for viability were run after 1, 2, 3 and 4 weeks of exposure to low oxygen conditions, at oxygen levels in the vessels maintained below 10 ppm. Treatment was later extended to 10 and 16 weeks. Tests included measurements of CO₂ production and determination of the ability of fungal tissue to regenerate. The effect of anoxic conditions on the mycelia of treated fungal species was expressed as an increased time needed for regeneration or as a complete absence of growth of inocula taken from the exposed cultures. The cultures that were retarded by the low-oxygen environment consequently produced less CO₂ per hour. For C. puteana cultures, the effects of anoxic treatment became apparent in the second week of the treatment. The number of affected cultures rose steadily with the prolongation of anoxic treatment. By the 16th week of the experiment, 80% of the inocula of C. puteana did not regenerate. A. vaillantii inocula regeneration was not affected until after the fourth week of treatment. The influence of anoxic treatment on the cultures of this species was more pronounced in the test on the 10th and especially on the 16th week, when 67% of inocula did not regenerate. Argon or nitrogen gas caused the same degree of loss of viability in both the fungal species tested. In general, A. vaillantii mycelial cultures proved to be less sensitive to anoxic conditions, caused by either argon and nitrogen gas.     

Effect of aeration on antibiotic production byStreptomyces clavuligerus

Summary During the rapid growth phase ofStreptomyces clavuligerus in a 10 litre fermentor, the level of dissolved oxygen (DO) was found to drop to almost zero for a period of approximately 10 h, delaying the appearance of and lowering the production of the antibiotic cephamycin C. Controlling the DO at either 50% or 100% throughout the fermentation did not significantly alter the specific growth rate of the culture, but did elevate final antibiotic levels two- and three-fold respectively. The improved oxygen availability affected antibiotic production both by increasing the rate of specific cephamycin C bisosynthesis and by maintaining this higher rate throughout the production period. These results demonstrate that controlling dissolved oxygen levels close to saturation during periods of rapid growth markedly improves the efficiency and duration of cephamycin C biosynthesis inS. clavuligerus.     

The role of oxygen availability in the embryonation of Heterakis gallinarum eggs

The importance of oxygen availability in the embryonation of the infective egg stages of the gastrointestinal nematode parasite Heterakis gallinarum was studied in the laboratory. Unembryonated H. gallinarum eggs were kept under either aerobic conditions by gassing with oxygen, or anaerobic conditions by gassing with the inert gas nitrogen, under a range of constant temperatures. Oxygenated eggs embryonated at a rate influenced by temperature. Conversely, eggs treated with nitrogen showed no embryonation although when these eggs were transferred from nitrogen to oxygen gas after 60 days of treatment, embryonation occurred. This demonstrated that oxygen is an essential requirement for H. gallinarum egg development, although undeveloped eggs remain viable, even after 60 days in low oxygen conditions. The effects of climate on the biology of free-living stages studied under constant laboratory conditions cannot be applied directly to the field where climatic factors exhibit daily cycles. The effect of fluctuating temperature on development was investigated by including an additional temperature group in which H. gallinarum eggs were kept under daily temperature cycles between 12 and 22°C. Cycles caused eggs to develop significantly earlier than those in the constant mean cycle temperature, 17°C, but significantly slower than those in constant 22°C suggesting that daily temperature cycles had an accelerating effect on H. gallinarum egg embryonation but did not accelerate to the higher temperature. These results suggest that daily fluctuations in temperature influence development of the free-living stages and so development cannot be accurately predicted on the basis of constant temperature culture.     

Physiology of nitrogen fixation in Azospirillum lipoferum Br 17 (ATCC 29 709)

Changes of cellular activities during batch cultures with Azospirillum lipoferum strain Br 17 (ATCC 29 709) were observed within the growth cycle, at optimal pO₂ (0.002–0.003 atm). The relative growth rate for cells growing with N₂ as sole nitrogen source during log phase was =0.13 h^-1 and the doubling time was 5.3 h. Nitrogenase activity was not accompanied by hydrogen evolution at any growth stage, and a very active uptake hydrogenase was demonstrated. The hydrogenase activity increased towards the end of the growth period when glucose became limiting and N₂ fixation reached its maximal specific activity. Oxygen consumption and oxygen tolerance at the various growth stages, increased simultaneously with the uptake hydrogenase activity indicating a possible role of this enzyme in an oxygen protection mechanism of A. lipoferum nitrogenase. The efficiency of nitrogen fixation expressed as mg total nitrogen fixed in cells and supernatant per g glucose consumed, was 20 at the early log phase and increased to 48 at the late log phase. About 25% of the total fixed nitrogen was recovered in the culture supernatant.Abbreviations DOT Dissolved oxygen tension - PHB Poly--hydroxybutyric acid - O.D. Optical density (560 nm) - A.T.C.C. American type culture collection - NTA Nitrilotriacetic acid Graduate student of the Universidade Federal Rural do Rio de Janeiro, Brazil     

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.     

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.     

Assessment of the tolerance of Lactococcus lactis cells at elevated temperatures

When Lactococcus lactis strains were exposed directly to the lethal temperature of 50 C for 30 ;min, 0.1–31% of the cells survived. However, when pre-exposed to 40 °C, prior to exposure at 50 °C, 4–61% of the cells survived. A plasmid carrying a unique heat shock gene from the thermophile Streptococcus thermophilus was cloned into L. ;lactis. When the transformed cells were cultivated at 30 °C the introduction of the plasmid had no obvious effect on the growth of L. ;lactis. However, when the temperature was abruptly shifted from 30 °C to 42 °C at mid-growth phase the growth decreased by 50%.     

The role of <Emphasis Type="Italic">Campsurus notatus</Emphasis> (Ephemeroptera: Polymitarcytidae) bioturbation and sediment quality on potential gas fluxes in a tropical lake

About 30% of the total area of Lake Batata (Amazon) was impacted by the disposal of bauxite tailings originated from the process of washing bauxite. This effluent, composed by fine particles of clay and water, settled on top of the natural sediment, originating a new substratum with a different physical and chemical composition. This phenomenon created a new distinct habitat (impacted sediment) influencing the benthic community. The aim of this study was to evaluate the impact of bioturbation by Campsurus notatus (Ephemeroptera: Polymitarcytidae) on potential gas fluxes in the sediment of natural and impacted areas of the lake. The natural sediment had a significantly higher methane concentration when compared to the impacted one. In incubated sediment cores, the presence of C. notatus nymphs resulted in a significant increase in oxygen consumption and methane and carbon dioxide release to the water column. The effect of the presence of nymphs on methane was ambiguous. The C. notatus nymphs strongly decreased methane concentration in natural sediment samples, probably because of the enhancement of the oxic sediment area. However, this effect was not observed in impacted samples. Finally, the new substratum of Lake Batata decreased methane concentration in sediment and water column. C. notatus nymphs demonstrated to have a significant role on gas flux (methane and CO₂) from sediment to water column as well as on oxygen consumption in Lake Batata, consequently influencing the carbon cycle in this lake. Handling editor: S. M. Thomaz     

In vivo inactivation of soluble hydrogenase of Alcaligenes eutrophus

The soluble, NAD⁺-reducing hydrogenase in intact cells of Alcaligenes eutrophus was inactivated by oxygen when electron donors such as hydrogen or pyruvate were available. The sole presence of either oxygen or oxidizable substrates did not lead to inactivation of the enzyme. Inactivation occurred similarly under autotrophic growth conditions with hydrogen, oxygen and carbon dioxide. The inactivation followed first order reaction kinetics, and the half-life of the enzyme in cells exposed to a gas atmosphere of hydrogen and oxygen (8:2, v/v) at 30° C was 1.5 h. The process of inactivation did not require ATP-synthesis. There was no experimental evidence that the inactivation is a reversible process catalyzed by a regulatory protein. The possibility is discussed that the inactivation is due to superoxide radical anions (O ₂ ^- ) produced by the hydrogenase itself.     

Oxygen loss from Spartina alterniflora and its relationship to salt marsh oxygen balance

Spartina alterniflora has been reported to lose significant amounts of oxygen to its rhizosphere with potentially important effects on salt-marsh biogeochemical cycling and plant productivity. The potential significance of this oxidative pathway was evaluated using laboratory split-chamber experiments to quantify oxygen loss from intact root systems under a wide variety of pre-treatment and incubation conditions including antibiotics to inhibit microbial respiration. The aerenchyma system of S. alterniflora was found to transport O₂, N₂, Ar, and CH₄ from above-ground sources to its below-ground roots and rhizomes. While non-respiratory gases were observed to move from the lacunae to water bathing the root systems, net O₂ loss did not occur; instead oxygen present outside of the roots/rhizomes was consumed. Net oxygen loss was found when resistance to gas transport was reduced in the lacunae-rhizosphere pathway by placing the root systems in a gas phase and when plant respiration was significantly reduced. Root system respiration appeared to be the major variable in the plant oxygen balance. When root and rhizome respiration was inhibited using poisons or lowered by cooling, the oxygen deficit was greatly reduced and oxygen loss was indicated. The effect of seasonal temperature changes on root system oxygen deficit presents a possible explanation as to why Spartina produces root systems with respiration rates that cannot be supported by gas transport. Overall, while oxygen loss from individual plant roots is likely, integrating measured root system oxygen loss with geochemical data indicates that the mass amount of oxygen lost from S. alterniflora root systems is small compared to the total oxygen balance of vegetated salt marsh sediments.     

Heat shock response ofChlorella protothecoides during greening

Heterotrophically grown cells ofChlorella protothecoides were transferred to autotrophic medium and allowed to green at 25°C. The protein synthetic activity of the greening cells measured in terms of incorporation of [³5S]-methionine showed a maximum around 20 h of greening and thereafter started declining. Similarly, an analysis of densitometric tracings of the fluorographic profile of the polypeptides associated with both total cellular fraction and membrane fractions during different hours of greening revealed that maximum number of polypeptides were getting labelled around 20 h of greening. At 20 h of greening, the cells were shifted to 40°C and the effect of heat shock on protein synthesis was studied. The heat shock treatment caused a definite decrease in the incorporation of [³⁵S]-methionine into proteins. Due to heat shock, the synthesis of total soluble proteins was affected much more than that of the thylakoid membrane bound proteins. When the cells were transferred back to 25°C after a brief period of heat shock at 40°C, there was a considerable recovery in the protein synthesis and this recovery was found to be significant in the case of soluble proteins, while there was no such definite recovery in the synthesis of thylakoid membrane bound proteins.     

Photoinhibition in vivo of Photosystem II reactions during developmentof the photosystems of wheat seedlings

Photoinhibition of O₂ evolution and reactions leading to millisecond-delayed light emission (ms-DLE) of chlorophyll by illumination of leaves with excess white light were investigated in wheat seedlings greened for different times in a special chamber with constant conditions (20°C; CO₂ and humidity). A sharp reduction in initial and steady state rates of O₂ evolution and in the intensity of different components of ms-DLE under excess light on the stage of lag-phase of chlorophyll biosynthesis (4–6h of greening) were observed. An increasing stability of the oxygen-evolving process and ms-DLE of chlorophyll during formation of the thylakoid membrane photosystems (12–24 h of greening) was shown. Rifampicin did not influence the stability of oxygen evolution whereas cycloheximide led to the intensification of photoinhibition of the initial and steady-state rates of oxygen evolution under the inhibitory light action. The early stages of photosystems formation during short time of greening of etiolated seedlings were more sensitive to the action of inhibitory light, possibly due to a weak interaction of the oxygen-evolving system components and connection with reaction centers of Photosystem II.     

Factors affecting the production of hydrogen sulphide by Lactobacillus sake L13 growing on vacuum-packaged beef

Lactobacillus sake L13 produced hydrogen sulphide during growth at 0°C on vacuum-packaged beef of normal pH (5·6–5·8) when the packaging films used had oxygen permeabilities as high as 200 ml/m²/24 h/atm (measured at 25°C and 98% relative humidity. No hydrogen sulphide was detected when the film permeability was 300 ml/m²/24 h/atm. Sulphmyoglobin was formed whenever hydrogen sulphide was present except when the film permeability was very low (1 ml of oxygen/m²/24 h/atm). Lactobacillus sake L13 also produced hydrogen sulphide when grown on beef under anaerobic conditions at 5°C. When meat pH was high (6·4–6·6) hydrogen sulphide was first detected after incubation for 9 d. When 250 μg of glucose was added to each g of high pH meat, or when meat pH was normal (5·6–5·8), hydrogen sulphide was first detected after incubation for 18 d. The spoilage of beef by hydrogen sulphide-producing lactobacilli is more rapid when the pH of the meat is high because high-pH meat contains less glucose. Sulphmyoglobin formation and greening can be prevented by the use of packaging films of very low oxygen permeability.     

Localization of light-harvesting complex apoproteins in the chloroplast and cytoplasm during greening ofChlamydomonas reinhardtii at 38°C

Assembly of the major light-harvesting complex (LHC II) and development of photosynthetic function were examined during the initial phase of thylakoid biogenesis inChlamydomonas reinhardtii cells at 38°C. Continuous monitoring of LHC II fluorescence showed that these processes were initiated immediately upon exposure of cells to light. However, mature-size apoproteins of LHC II (Lhcb) increased in amount in an alkali-soluble (non-membrane) fraction in parallel with the increase in the membrane fraction. Alkali-soluble Lhcb were not integrated into membranes when protein synthesis was inhibited, suggesting that they were not active intermediates in LHC II assembly, nor were they recovered in a purified chloroplast preparation. Immunocytochemical analysis of greening cells revealed Lhcb inside the chloroplast near the envelope and in clusters deeper in the organelle. Antibody binding also detected Lhcb in granules within vacuoles in the cytosol, and Lhcb were recovered in granules purified from greening cells. Our results suggest that the cytosolic granules serve as receptacles of Lhcb synthesized in excess of the amount that can be accommodated by thylakoid membrane formation within the plastid envelope.     

Investigation of the behavior of dissolved gases during freezing

This paper deals with the freezing process of aqueous solutions of gases and the nucleation of gas bubbles at the moving ice—water interface. A cryomicroscope was used to investigate the conditions of nucleation and growth of bubbles after reaching a stationary concentration profile ahead of the phase boundary. The enrichment of gases due to the distribution coefficient was detected by means of a test bubble method, i.e., the increase in the radius of a small bubble being approached by the ice front. A distribution coefficient of 0.048 (at 0 °C) was found for oxygen. Nucleation occurs when stationary growth conditions in the solution are reached. The measured oversaturation is close to 20, i.e., about the inverse of the distribution coefficient. In highly saturated gas solutions, dendritic breakdown of the planar ice-water interface due to gas enrichment could be observed. At these positions also a considerable degree of constitutional supercooling was found. Bubbles were nucleated in interdendritic spaces. Nucleation and growth of gas bubbles was seen to be a periodic process under certain circumstances which can be explained by the continuous buildup and reduction of the concentration field in the remaining solution. The growth kinetics of the bubbles and their maximum size are governed by the velocity of the ice-water interface. During growth the gas bubbles are pushed and partially encapsulated, until they reach a radius in the order of magnitude of the diffusion boundary layer of the concentration profile, and become totally engulfed by the solid phase.     

Differential sensitivity of green algae to allelopathic substances from Chara

Three short-term laboratory experiments were conducted to investigate allelopathic effects of a mixture of Chara globularis var. globularis Thuillier and Chara contraria var. contraria A. Braun ex Kützing on three different green algae. Single phytoplankton species were exposed to filtered water originating from charophyte cultures. Phytoplankton growth was monitored by determination of chlorophyll concentrations in batch cultures. The change in chlorophyll concentration during the experiments was analysed with a logistic growth model, resulting in an estimate of the exponential growth rate and the duration of the lag phase of the single green algae. The results indicate allelopathic effects of Chara on the growth of the green algae Selenastrum capricornutum Printz and Chlorella minutissima Fott et Nováková, whereas Scenedesmus obliquus (Turpin) Kützing did not seem to be affected. The exponential growth rate of S. capricornutum decreased 7% in the presence of water from a charophyte culture, while the growth rate of C. minutissima decreased with 3%. The allelopathic effect of Chara did not increase when the green alga C. minutissima was P-limited. The effect of Chara was different when young sprouts were used. With young sprouts the duration of the lag phase of C. minutissima was extended (25%), whilst for old plants the growth rate of this green alga decreased. Although the inhibiting effect of charophytes on specific phytoplankton species is rather small, the differential sensitivity of the species to Chara might influence the composition and biomass of phytoplankton communities in the field.