Shear stress effects on cell growth and <Emphasis Type="SmallCaps">L</Emphasis>-DOPA production by suspension culture of <Emphasis Type="Italic">Stizolobium hassjoo</Emphasis> cells in an agitated bioreactor

Suspension cultures of Stizolobium hassjoo cells were cultivated in a 7l bioreactor. The growth rate and intracellular L-DOPA content of the cells using two different turbine impellers were compared. There were distinct differences in growth behavior and L-DOPA productivity in the range of 100 to 500 rpm for flat-blade turbine impeller. Disk turbine retarded significantly the cell growth but not so significantly for L-DOPA production in the range of 200 to 300 rpm. The shear force intensity of the two impellers at various rotational rates was compared with shear force index (SFI), and power input per unit mass and eddy length scale. There was good consistency among the three indexes for shear force intensity. Thus with SFI the shear force intensity of bioreactor can be indirectly estimated. A critical shear stress that may cause sublytic effect in cells was identified for flat-blade turbine operated at 400 rpm. The common effect between the shear stress and the proton elicitation in the bioreactor was elucidated with a hypothesis of signal transduction by second messenger, H⁺. Our results suggested that H⁺ transduced the signal to protoplast when S. hassjoo cells were stimulated by shear stress. This resulted in an increase of H⁺ which triggered a similar reaction to the pH control of culture broth and enhanced the L-DOPA production.     

Tight control of growth and cell differentiation in photoautotrophically growing moss (<Emphasis Type="Italic">Physcomitrella</Emphasis><Emphasis Type="Italic">patens</Emphasis>) bioreactor cultures

The use of the moss Physcomitrella patens as a production system for heterologous proteins requires highly standardised culture conditions. For this purpose a semi-continuous photoautotrophic bioreactor culture of Physcomitrella was established. This culture grew stably for 7 weeks in a 5-l bioreactor with a dilution rate of 0.22/day. Enrichment of the air for aeration in a batch bioreactor culture with 2% (v/v) CO₂ resulted in an increase in the specific growth rate to 0.57/day. Changes in the pH of the semi-continuous bioreactor culture medium between pH 4.5 and pH 7.0 influenced protonema differentiation; however it did not negatively affect the growth rate compared to uncontrolled pH. The advantages of Physcomitrella as a system for the production of heterologous proteins in plants are discussed.     

K L a Evaluation during the course of fermentation using data reconciliation techniques

The oxygen mass transfer coefficient often serves to compare the efficiency of bioreactors and their mixing devices as well as being an important scale-up factor. In submerged fermentation, four methods are available to estimate the overall oxygen mass transfer coefficient (K_La): the dynamic method, the stationary method based on a previous determination of the oxygen uptake rate (Q_O2X), the gaseous oxygen balance and the carbon dioxide balance. Each method provides a distinct estimation of the value of K_La. Data reconciliation was used to obtain a more probable value of K_La during the production of Saccharomyces cerevisiae, performed in 22.5-l fed-batch bioreactor. The estimate of K_La is obtained by minimising an objective function that includes measurement terms and oxygen conservation models, each being weighted according to their level of confidence. Weighting factors of measurement terms were taken as their respective inverse variance whereas weighting factors of oxygen conservation models were obtained using Monte Carlo simulations. Results show that more coherent and precise estimations of K_La are obtained.     

Dormancy in Seeds of Charlock: IV. INTERRELATIONSHIPS OF GROWTH, OXYGEN SUPPLY AND CONCENTRATION OF INHIBITOR

Respiration measurements were made over a period of 24 h at25 °C on seeds and excised embryos maintained in Warburgflasks with partial pressures of oxygen ranging from 0 to 1atm. In the initial phase (0 to 4 h), the rate of oxygen uptake(Q_O2 of excised embryos increased linearly with external oxygenconcentration (C_O from 0 to 0.1 atm O₂ from 0.1 to 0.2 atm O₂the relation was curvilinear, and from 0.2 to 1.0 atm O₂ uptakewas independent of concentration. In later stages the relationbetween Q_O2 and C_o changed, and from 20 to 24 h the rate ofoxygen uptake increased with concentration to 1.0 atm O₂. Thechanges with time were associated with increase in rate of respiration,increase in cell size and cell number, and the oxidation offats. The decline in concentration of oxygen from the surfaceto the centre of embryos was calculated to be relatively smallat each external oxygen concentration. Althugh the rate of diffusionfailed to keep pace with consumption, the main parameters whichdetermined the internal oxygen status of the embryos were thesurface concentrations and the permeability of the seed coat.The resistance of the seed coat to diffusion of oxygen was foundto be very high, the coefficient of diffusion being about 10^–7mm² s^–1. The concentration of oxygen and in air were estimatedto be approximately 0.04 and 0.02 atm O₂, respectively. Sincea smaller concentration of oxygen (0.012 atm O₂) in the tissueswas found to be sufficient for growth, the dormancy of the seedswas not due to lack of oxygen. Dormancy appeared to be due tothe activity of growth-inhibiting substances, the concentrationof which increased with decrease in oxygen supply; below 0.1atm O₂ their rate of production increased with decrease in theoxygen concentration of the tissues. They accumulated withinthe testas of dormant seeds and prevented cell elongation. Extractsof the inhibitory substances were partially purifield by partitioningthe aqueous fraction with ether and separating chromatographically.The active principle(s) was not abscisic acid ((+)—AbscisinII, ‘Dormin’) or the mustard oil, allylisothiocyanate.     

Effects of Atmospheric O3 on Azolla-Anabaena Symbiosis

Cultures of water fern Azolla pinnata R. Br. exposed for 1 weekto either 30, 50 or 80 nl l^-1 O₃ showed significant reductionsin rates of growth and N₂ fixation, and had fewer heterocysts.Although the levels of glutamine synthetase (GS) and glutamatedehydrogenase (GDH) activity were decreased by low concentrationsof O₃ exposures (30 or 50 nl l^-1), significant increases inlevels of the same enzymes were caused by higher concentrationsof O₃ (80 nl l^-1). Increased levels of total protein, polyamines(putrescine and spermidine), and the xanthophyll-cycle precursorof abscisic acid (ABA), violaxanthin, were also found with higherlevels of O₃ (80 nl l^-1). Levels of ABA itself were significantlyincreased by low level O₃ fumigation (30 nl l^-1) but significantlydecreased by exposure to 80 nl l^-1 O₃. This may indicate thathigher levels of atmospheric O₃ inhibit the final stages ofABA biosynthesis from violaxanthin.Copyright 1994, 1999 AcademicPress Abscisic acid, nitrogen assimilation, nitrogen fixation, ozone pollution, polyamines, violaxanthin     

Effects of elevated CO<Subscript>2</Subscript> on foliar chemistry of saplings of nine species of tropical tree

This study examined the effects of elevated CO₂ on secondary metabolites for saplings of tropical trees. In the first experiment, nine species of trees were grown in the ground in open-top chambers in central Panama at ambient and elevated CO₂ (about twice ambient). On average, leaf phenolic contents were 48% higher under elevated CO₂. Biomass accumulation was not affected by CO₂, but starch, total non-structural carbohydrates and C/N ratios all increased. In a second experiment with Ficus, an early successional species, and Virola, a late successional species, treatments were enriched for both CO₂ and nutrients. For both species, nutrient fertilization increased plant growth and decreased leaf carbohydrates, C/N ratios and phenolic contents, as predicted by the carbon/nutrient balance hypothesis. Changes in leaf C/N levels were correlated with changes in phenolic contents for Virola (r=0.95, P<0.05), but not for Ficus. Thus, elevated CO₂, particularly under conditions of low soil fertility, significantly increased phenolic content as well as the C/N ratio of leaves. The magnitude of the changes is sufficient to negatively affect herbivore growth, survival and fecundity, which should have impacts on plant/herbivore interactions.     

Transformation of elite white maize using the particle inflow gun and detailed analysis of a low-copy integration event

Elite white maize lines W506 and M37W were transformed with a selectable marker gene (bar) and a reporter gene (uidA) or the polygalacturonase-inhibiting protein (pgip) gene after bombardment of cultured immature zygotic embryos using the particle inflow gun. Successful transformation with this device did not require a narrow range of parameters, since transformants were obtained from a wide range of treatments, namely pre-culture of the embryos for 4-6 days, bombardment at helium pressures of 700-900 kPa, selection-free culture for 2-4 days after bombardment and selection on medium containing bialaphos at 0.5-2 mg l^-1. However, bombardments with helium pressures below 700 kPa yielded no transformants. The culture of immature zygotic embryos of selected elite white maize lines on medium containing 2 mg l^-1 2,4-dichlorophenoxyacetic acid and 20 mM L-proline proved to be most successful for the production of regenerable embryogenic calli and for the selection of putative transgenic calli on bialaphos-containing medium after transformation. Transgenic plants were obtained from four independent transformation events as confirmed by Southern blot analysis. Transmission of the bar and uidA genes to the T₄ progeny of one of these transformation events was demonstrated by Southern blot analysis and by transgene expression. In this event, the transgenes bar and uidA were inserted in tandem.     

Effects of a Range of O2 Concentrations on Porosity of Barley Roots and on their Sugar and Protein Concentrations

Barley was grown at a range of oxygen concentrations (0.5–9mg l^–1), in nutrient solutions. Growth of both shootsand seminal roots was restricted by O₂ concentrations lowerthan 2–3 mg l^–1) but nodal root growth was not. Root porosities were increased even at those O₂ concentrationswhich did not restrict growth, and were inversely proportionalto the protein levels of the roots. Sugar concentrations increasedappreciably only at those O₂ concentrations which also restrictedgrowth. Hordeum vulgare L., barley, root porosity, sugar, protein, oxygen concentration     

Microbial community composition and function beneath temperate trees exposed to elevated atmospheric carbon dioxide and ozone

We hypothesized that changes in plant growth resulting from atmospheric CO₂ and O₃ enrichment would alter the flow of C through soil food webs and that this effect would vary with tree species. To test this idea, we traced the course of C through the soil microbial community using soils from the free-air CO₂ and O₃ enrichment site in Rhinelander, Wisconsin. We added either ¹³C-labeled cellobiose or ¹³C-labeled N-acetylglucosamine to soils collected beneath ecologically distinct temperate trees exposed for 3 years to factorial CO₂ (ambient and 200 µl l^-1 above ambient) and O₃ (ambient and 20 µl l^-1 above ambient) treatments. For both labeled substrates, recovery of ¹³C in microbial respiration increased beneath plants grown under elevated CO₂ by 29% compared to ambient; elevated O₃ eliminated this effect. Production of ¹³C-CO₂ from soils beneath aspen (Populus tremuloides Michx.) and aspen-birch (Betula papyrifera Marsh.) was greater than that beneath aspen-maple (Acer saccharum Marsh.). Phospholipid fatty acid analyses (¹³C-PLFAs) indicated that the microbial community beneath plants exposed to elevated CO₂ metabolized more ¹³C-cellobiose, compared to the microbial community beneath plants exposed to the ambient condition. Recovery of ¹³C in PLFAs was an order of magnitude greater for N-acetylglucosamine-amended soil compared to cellobiose-amended soil, indicating that substrate type influenced microbial metabolism and soil C cycling. We found that elevated CO₂ increased fungal activity and microbial metabolism of cellobiose, and that microbial processes under early-successional aspen and birch species were more strongly affected by CO₂ and O₃ enrichment than those under late-successional maple.     

The effect of elevated carbon dioxide and ozone on leaf- and branch-level photosynthesis and potential plant-level carbon gain in aspen

Two aspen (Populus tremuloides Michx.) clones, differing in O₃ tolerance, were grown in a free-air CO₂ enrichment (FACE) facility near Rhinelander, Wisconsin, and exposed to ambient air, elevated CO₂, elevated O₃ and elevated CO₂+O₃. Leaf instantaneous light-saturated photosynthesis (P_S) and leaf areas (A) were measured for all leaves of the current terminal, upper (current year) and the current-year increment of lower (1-year-old) lateral branches. An average, representative branch was chosen from each branch class. In addition, the average photosynthetic rate was estimated for the short-shoot leaves. A summing approach was used to estimate potential whole-plant C gain. The results of this method indicated that treatment differences were more pronounced at the plant- than at the leaf- or branch-level, because minor effects within modules accrued in scaling to plant level. The whole-plant response in C gain was determined by the counteracting changes in P_S and A. For example, in the O₃-sensitive clone (259), inhibition of P_S in elevated O₃ (at both ambient and elevated CO₂) was partially ameliorated by an increase in total A. For the O₃-tolerant clone (216), on the other hand, stimulation of photosynthetic rates in elevated CO₂ was nullified by decreased total A.     

Influence of putrescine, silver nitrate and polyamine inhibitors on the morphogenetic response in untransformed and transformed tissues of Cichorium intybus and their regenerants

The addition of 40 mM putrescine (Put) to Murashige and Skoog's (MS) medium resulted in increased shoot multiplication and shoot growth in untransformed plants relative to transformed plants of Cichorium intybus L. Put at a concentration of 40 mM also resulted in flowering in both systems on the 28th day, with elevated titers of endogenous conjugated Put and spermine (Spm) in both untransformed and transformed plants. The addition of 40 µM AgNO₃ to untransformed axillary buds of C. intybus L. cultured on MS media resulted in increased shoot multiplication (36.9DŽ.63 shoots per culture) and increased shoot growth (7.82ǂ.76 cm) as compared to transformed ones (11.6ǂ.89 shoots per culture; 3.20ǂ.24 cm). Moreover, cultures treated with 40 µM AgNO₃ showed in vitro flowering on the 28th day in both systems, with the endogenous levels of conjugated spermine being higher in untransformed plants than in transformed ones. The morphogenetic response and the endogenous conjugated pool of polyamines were lower following !-DL-difluromethylarginine and !-DL-difluromethylornithine treatments; the addition of put (40 mM) and AgNO₃ (40 µM) restored these to normal levels. Under exogenous put feeding, ethylene production was lower in both the untransformed and transformed cultures. We believe that an interplay between polyamine and ethylene biosynthesis is involved in regulating the morphogenetic response in both transformed and untransformed shoots of C. intybus. The response to AgNO₃ and Put treatment was not altered by the transformation process.     

Possible physiological mechanisms for production of hydrogen peroxide by the ichthyotoxic flagellate Heterosigma akashiwo

Blooms of the toxic red tide phytoplankton Heterosigma akashiwo(Raphidophyceae) are responsible for substantial losses withinthe aquaculture industry. The toxicological mechanisms of H.akashiwoblooms are complex and to date, heavily debated. One putativetype of ichthyotoxin includes the production of reactive oxygenspecies (ROS) that could alter gill structure and function,resulting in asphyxiation. In this study, we investigated thepotential of H.akashiwo to produce extracellular hydrogen peroxide,and have investigated which cellular processes are responsiblefor this production. Within all experiments, H.akashiwo producedsubstantial amounts of hydrogen peroxide (up to 7.6 pmol min^–110⁴ cells^–1), resulting in extracellular concentrationsof ~0.5 µmol l^–1 H₂O₂. Measured rates of hydrogenperoxide production were directly proportional to cell density,but at higher cell densities, accuracy of H₂O₂ detection wasreduced. Whereas light intensity did not alter H₂O₂ production,rates of production were stimulated when temperature was elevated.Hydrogen peroxide production was not only dependent on growthphase, but also was regulated by the availability of iron inthe medium. Reduction of total iron to 1 nmol l^–1 enhancedthe production of H₂O₂ relative to iron replete conditions (10µmol l^–1 iron). From this, we collectively concludethat production of extracellular H₂O₂ by H.akashiwo occurs througha metabolic pathway that is not directly linked to photosynthesis.     

Feasibility of culturing C2C12 mouse myoblasts on glass microcarriers in a continuous stirred tank bioreactor

Commercial culturing of mammalian cell lines is increasing in importance as more biological products unique to mammals are being produced in genetically altered mammalian cells. Most mammalian cells are anchorage dependent, so they must be cultured on a support matrix. This limitation, along with the requirement of a low shear environment, severely effects the scale-up of bench-scale culture systems. The need to culture mammalian cells on a support matrix limits the increase in cell population to a factor of 10-20 before growth virtually stops due to contact inhibition. Commercial culturing systems for anchorage dependent cells are batch processes because of the combination of contact inhibition and support matrix requirements. Development of a continuous bioreactor system could allow both unlimited scale-up and continuous cell-mass production. To design a continuous reactor, a mathematical model to predict the reactor performance should be developed. This paper addresses the development of a mathematical model for predicting continuous bioreactor performance. It was found that anchorage dependent C2C12 mouse myoblast cells, a continuous cell line, followed Monod kinetics for glucose consumption and cell mass production in batch flask experiments, with w_max = 0.040 hr^у and K_m = 2.5 mM. Furthermore, it was found that these parameters could be used to predict the glucose consumption in a continuous bioreactor operated with constant feed of seeded microcarriers operated at two different residence times. The success of this model implies the possibility of developing a continuous cell harvesting and reinoculation system using a microcarrier bioreactor to produce cell mass.     

Effects of Bicarbonate and Carbon Dioxide on the Competition between Chlorella vulgaris and Spirulina platensis

A concentration of 0.05 M bicarbonate and over exerted an increasinglyinhibitory effect on the growth of Chlorella vulgaris, whereasa concentration lower than 0.1 M decreased the growth rate ofSpirulina platensis. In a medium containing 0.15 M bicarbonateand 0.05 M NaCl, in which the growth of Chlorella was curtailed,it was possible to maintain a mixed, continuous culture of Chlorellaand Spirulina at steady state. Carbon dioxide also exerted adecisive influence on the outcome of the competition betweenthe two algae. In a mixed culture at steady state, an immediateand sharp decline in the population of Chlorella was evidentas soon as CO₂ bubbling was withheld. Prevention of the risein pH did not prevent the fast increase in the number of Chlorellacells. When the supply of CO₂ was resumed just before Chlorellawas washed out, a complete recovery of the population of Chlorellatook place. The growth of Chlorella in above 0.1 M bicarbonatewas only possible when gaseous CO₂ was passed through the medium.High bicarbonate content and low concentrations of gaseous CO₂were identified as the major factors that prevented the contaminationof Spirulina cultures by Chlorella. (Received December 25, 1981; Accepted October 15, 1982)     

Vitis vinifera culture in a non-conventional bioreactor: the reciprocating plate bioreactor

This paper is concerned with the potential use of a reciprocating plate bioreactor (RPB) for suspended plant cell cultures. The agitation mechanism of the RPB system, a plate stack, was first evaluated in pure water and in pseudocells medium of 20, 40 and 60% of PCV. As the pseudocell concentration increases, the oxygen mass transfer coefficient, K_La, significantly decreases. Correlations were established for each plate stack and concentration with good prediction of K_La. Three fermentations were performed with Vitis vinifera cells, two in the RPB system and one in shake flasks. Shake flask cultures showed better performance whereas the first fermentation performed with the RPB showed the lowest performance. The lower growth observed was attributed to the operating conditions for aeration and the dissolved oxygen control strategy. CO₂ stripping in the initial portion of the fermentation led to lower biomass growth. The second fermentation, with more appropriate operating conditions, appears to follow the trend of shake flask cultures but was terminated after 5 days due to contamination. The RPB has the potential to be used for suspended plant cell cultures but significant research needs to be performed to find optimal operating conditions but, more importantly, to make appropriate modifications to ensure the sterility of the bioreactor over long time periods.     

Tissue structure and respiration of stems of <Emphasis Type="Italic">Betula pendula</Emphasis> under contrasting ozone exposure and nutrition

Tissue structure and respiration (Rs) of stems were analyzed in Betula pendula grown throughout the growing season in either filtered air (control) or 90/40 nl O₃ l^-1 (day/night). Both regimes were split into high and low nutrient supply. High nutrition increased tissue and cell sizes within the stem xylem, phloem and periderm, whereas ozone (O₃) tended to reduce tissue widths, inhibiting in particular the cambial activity of xylem growth in low-fertilized, O₃-exposed plants (O₃/LF). Callose deposition was enhanced in the phloem sieve plates and tannins tended to condense in vacuoles of parenchyma cells under O₃ stress. Decline occurred close to lenticels, related to O₃ impact during shoot differentiation and was probably exacerbated by the limited assimilate translocation. Radial stem growth ceased 4 weeks earlier than in control plants; however, the area-based Rs was enhanced during intense growth in high-fertilized, O₃-exposed plants. Photosynthetic CO₂ refixation of stems reached about 50% of their dark respiration rate and the relative growth rate (RGR) did not differ between treatments. At high nutrition, RGR enhanced Rs to levels twice as high as the maintenance level. Unit construction costs appeared to be similar in each treatment, although CO₂ release on a volume-increment basis was lowered by 45% in O₃/LF plants. This latter effect is ascribed to lowered maintenance demands of a xylem remaining reduced in width by 50%. The high respiratory costs in the carbon balance of O₃/LF plants result from an enhanced leaf rather than stem respiration, given the high demand for stress compensation in the foliage.     

Sugar Accumulation in Barley and Rice Grown in Solutions with low Concentrations of Oxygen

Barley and rice, at the early tillering stage, were grown inaerated nutrient solutions (> 7 mg O₂ l^–1) and transferredto solutions of low O₂ concentrations (< 0.5 mg l ^–1). For barley, low O₂ concentrations during the first 5 days severelyinhibited growth of seminal roots had less effect on nodal roots,and did not reduce shoot growth. Longer exposure to low O₂ concentrationsreduced shoot as well as root growth. Sugar concentrations inroots and shoots increased within 7 h after transfer of plantsto low O₂ concentrations. After 5 days at low O₂ concentrationssugar concentrations were very high in fast growing nodal rootsand in shoots, as well as in the slower growing seminal roots. In rice, low O₂ concentrations increased sugar levels of rootsduring summer, but not during winter. In summer, the highersugar levels at low O₂ concentrations persisted throughout adiurnal cycle. In root apices, sugar concentrations were increasedby low O₂ concentrations, even though the experiment was donein winter and the bulk of the root system showed no differencein sugar levels. The data indicate that sugar accumulation, at low O₂ concentrations,is caused by reduced growth and also that even apices of rootsgrown at low O₂ concentrations have sufficient substrates forrespiration. Hordeum vulgare L, barley, Oryza sativa L, rice, sugar accumulation, oxygen concentration     

In situ oxygen microelectrode measurements of bottom-ice algal production in McMurdo Sound, Antarctica

In-situ estimates of fast-ice algal productivity at Cape Evans, McMurdo Sound, in 1999 were lower than at the same site in previous years. Under-ice irradiance was between 0 and 8 µmol photons m^-2 s^-1; the ice was between 1.9 and 2.0 m thick and the algal biomass averaged 150 mg chl a m^-2, although values as high as 378 mg chl a m^-2 were recorded. Production on 11 and 12 November was between 0.053 and 1.474 mg C m^-2 h^-1. When the data from 11 November were fitted to a hyperbolic tangent function, a multilinear regression gave estimates for P_max of 0.571 nmol O₂ cm^-2 s^-1, an ! of 0.167 nmol O₂ cm^-2 s^-1 µmol^-1 photons m^-2 s^-1 and an E_k of 3.419 µmol photons m^-2 s^-1. A P_max of 2.674 nmol O₂ cm^-2 s^-1, an ! of 0.275 nmol O₂ cm^-2 s^-1 µmol^-1 photons m^-2 s^-1, r of 0.305 nmol O₂ cm^-2 s^-1 and an E_k of 9.724 µmol^-1 photons m^-2 s^-1 were estimated from the 12 November data. The sea-ice algal community was principally comprised of Nitzschia stellata, Entomoneis kjellmanii and Berkeleya adeliensis. Other taxa present included N. lecointei, Fragilariopsis spp., Navicula glaciei, Pleurosigma spp. and Amphora spp. Variations in the method for estimating the thickness of the diffusive boundary layer were not found to significantly affect the measurements of oxygen flux. However, the inability to accurately measure fine-scale variations in biomass is thought to contribute to the scatter of the P versus E data.     

Comparative study of the fermentation of D-glucose/D-xylose mixtures with Pachysolen tannophilus and Candida shehatae

We have performed a comparative analysis of the fermentation of the solutions of the mixtures of D-glucose and D-xylose with the yeasts Pachysolen tannophilus (ATCC 32691) and Candida shehatae (ATCC 34887), with the aim of producing bioethanol. All the experiments were performed in a batch bioreactor, with a constant aeration level, temperature of 30v°C, and a culture medium with an initial pH of 4.5. For both yeasts, the comparison was established on the basis of the following parameters: maximum specific growth rate, biomass productivity, specific rate of substrate consumption (q_s) and of ethanol production (q_E), and overall ethanol and xylitol yields. For the calculation of the specific rates of substrate consumption and ethanol production, differential and integral methods were applied to the kinetic data. From the experimental results, it is deduced that both Candida and Pachysolen sequentially consume the two substrates, first D-glucose and then D-xylose. In both yeasts, the specific substrate-consumption rate diminished over each culture. The values q_s and q_E proved higher in Candida, although the higher ethanol yield was of the same order for both yeasts, close to 0.4 kg kg^у.     

Hypoxia affects root sodium and chloride concentrations and alters water conductance in salt-treated jack pine (<Emphasis Type="Italic">Pinus banksiana</Emphasis>) seedlings

The effects of NaCl were studied in 6-month-old jack pine (Pinus banksiana Lamb.) seedlings growing in solution culture under hypoxic (approximately 2 mg l^у O₂) and well-aerated (approximately 8 mg l^у O₂) conditions. The results showed that hypoxia led to further reduction of stomatal conductance (g_s) in plants treated with 45 mM NaCl. This effect was likely due to a reduction in root hydraulic conductance by both stresses. When applied individually or together, neither 45 mM NaCl nor hypoxia affected cell membrane integrity of needles as measured by tissue electrolyte leakage. Hypoxia did not alter shoot Na⁺ and Cl^m concentrations in NaCl-treated plants. However, root Na⁺ concentrations were lower in NaCl-treated hypoxic plants, suggesting that hypoxia affected the ability of roots to store Na⁺. Hypoxia also induced root electrolyte leakage from NaCl-treated and control plants. The higher root Cl^m concentrations compared with Na⁺ and the positive correlation between root Cl^m concentrations and electrolyte leakage suggest that Cl^m played a major role in salt injury observed in jack pine seedlings. Roots of well-aerated plants treated for 1 week with NaCl contained almost two-fold higher concentration of total non-structural carbohydrates compared with plants from other experimental treatments and these concentrations decreased in subsequent weeks. We suggest that under prolonged hypoxic conditions, roots lose the ability to prevent Cl^m uptake resulting in the increase in root Cl^m concentration, which has damaging effects on root cell membranes.