Modelling the uptake of nitrate by a growing plant with an adjustable root nitrate uptake capacity

A new model is presented to predict the plant uptake of nitrate supplied by diffusion and mass flow to its roots. Plant growth, root-shoot ratio and the plant's nitrate uptake capacity are all set dependent on the plant's N nutrition state. By thoroughly integrating processes occurring in both plant and soil, the model enables to control the relative importance of both under a wide range of different nutritional scenarios.Soil parameters D₀ diffusion coefficient in water (m² day^-1) - D_e diffusion coefficient in soil (m² day^-1) - C nitrate concentration in soil (mol m^-3) - f tortuosity (-) - volumetric moisture content (-) - R radial distance from root axis (m) Plant parameters b₁, b₂ parameters of biomass partitioning Equation (10) - IR interroot distance (m) - K_mU Michaelis-Menten constant of the uptake system (mol m^-3) - K_mNRA Michaelis-Menten constant of nitrogen reduction system (mol g^-1) - k₁, k₂, k₃ parameters of growth model Equation (9) - L_v Root length density (m m^-3) - NO_{3 set} ^- Set point of the cytoplasmatic nitrate pool (mol g^-1 dw) - NO_{3 c} ^- cytoplasmatic nitrate concentration (mol g^-1 dw) - NO_{3 v} ^- vacuolar nitrate concentration (mol g^-1 dw) - NRA_max maximum nitrate reductase activity (mol g^-1 dw day^-1) - N_re reduced nitrogen content (mol) - N_remax maximum reduced N concentration in the plant (mol g^-1 dw) - P partitioning coefficient of nitrate between cyplasm and vacuole - R(1) root radius (m) - RGR relative growth rate (day^-1) - U uptake rate (mol day^-1 m^-2) - U_max maximum uptake rate (Eq. 6) (day^-1 m^-2) - Vo water flux at root surface (m day^-1) - W_r root dry weight (g) - W_sh shoot dry weight (g) - X model parameter: number of root compartments - Y model parameter: number of nodes     

Diurnal nitrate uptake in young tomato (Lycopersicon esculentum Mill.) plants: test of a feedback-based model

A simple model is proposed to describe diurnal net nitrate uptake rate patterns observed experimentally on young plants grown under constant non-limiting nutrition. It rests on two hypotheses: net uptake rate is under negative feedback control by internal plant nitrate content, and nitrogen metabolism occurs only during the light period. The model parameters were determined from the results of three independent experiments performed under non-disturbing conditions in a growth room at constant air and solution temperatures. Net hourly nitrate uptake rate was measured through a diurnal cycle and after an extended 28 h period of darkness. It increased continuously during the light period and decreased during the dark period. Under prolonged darkness, net uptake declined to an asymptotic positive uptake rate of about 10^-5 mol h^-1 g^-1 total plant dry weight. The measured hourly nitrate uptake rate values were consistent with independent determinations of long-term nitrate and total N accumulations in the plant. Realistic simulations of experimental data are achieved with the proposed model. Furthermore, the maintenance of a positive net uptake rate, measured in non-growing plants subjected to prolonged darkness, is explained in the model by the continuous increase of plant water content. The importance of the diurnal variations of plant water content for nitrate uptake rate is emphasized and gives consistency to the homeostasis hypothesis of the model. The diurnal changes in nitrate uptake predicted by the model are strongly dependent on the assumption made for diurnal changes in nitrate assimilation. While the purely photosynthetic assumption is convenient, a more realistic metabolism sub-model is needed.     

Seasonal variation in the nitrate content of water hyacinth (Eichhornia crassipes [Mart.] solms)

Water hyacinth was cultured in a flow-through system with constant nutrient availability and 1.4 mg 1^?1 NO₃-N as the nitrogen source. Tissue nitrate content ranged from 0.05 to 0.21% of dry wt. and accounted for 1.7–6.6% of the total nitrogen in the plant. Highest tissue nitrate levels occurred during the winter period of low plant growth rates and decreased as dry matter productivity increased. In the winter, the nitrate content of water hyacinth exceeded levels considered safe for conventional forage crops used for livestock feed.     

Ultrastructural and biophysical changes in developing embryos of Aesculus hippocastanum in relation to the acquisition of tolerance to drying

Changes in ultrastructural, biochemical and biophysical characteristics of embryonic axes of Aesculus hippocastanum during development are related to changing levels of desiccation tolerance. Histodifferentiation was complete 30 days after flowering (DAF) and fruits were shed about 120 DAF. During this period, the dry mass of embryonic axes increased from about 0.5 to 4 mg and the water content decreased from 10.2 to 2.0 g H₂O g^?1 dry mass (g g^?1). In spite of the large changes in water content, water potentials of freshly harvested material declined slightly during development from ?0.65 to ?2.0 MPa. Tolerance of desiccation increased as embryos matured. If evaluated on the basis of critical water contents for survival, tolerance appeared to increase continuously, maximum tolerance being achieved at 120 DAF when embryos survived water contents as low as 0.30 g g^?1. When evaluated from critical water potentials, three distinct levels of desiccation tolerance could be recognized at ?1.8 MPa (30-40 DAF), ?4 M Pa (48-90 DAF) and ?12 MPs (100-120 DAF). During development, total dry matter increased while sugar content (g g^?1' dry mass) and osmotically active material (mmol g^?1 dry mass) decreased. The subcellular organisation of axes was always typical of metabolically active tissues. Maximum tolerance (?12 MPa) was associated with a reduced amount of monosaccharides and the appearance of water with unusual calorimetric behaviour. Our data are consistent with several of the current hypotheses regarding the mechanisms of desiccation tolerance. Accumulation of dry matter reserves, reduced levels of monosaccharides, presence of dehydrin-like proteins and ability to form glasses appear to be associated with the changes in desiccation tolerance. However, none of these factors allow A. hippocastanum embryos to achieve the extreme level of desiccation tolerance typical of orthodox seeds. This may be because A. hippocastanum embryos do not reach physiological maturity and remain metabolically active even after they are shed from the parent plant. Also, embryos may acquire incompetent protectants or lack as yet unidentified protective mechanisms.     

Effects of prolonged iron loading in the rat using both parenteral and dietary routes.

Female Porton rats have been treated with either parenteral iron (intraperitoneal red cells) or dietary iron (carbonyl iron) for up to 12 months or 22 months respectively. In the parenteral iron loaded animals, the liver iron concentration rose from approximately 2 mg g^-1 dry wt at 2 months to 21 mg g^-1 dry wt at 12 months, while for the dietary iron loaded animals, this value rose from 14 to 48 mg g^-1 dry wt at 12 months to over 60 mg g^-1 dry wt after 22 months. In contrast, splenic iron concentrations rose more in the parenterally loaded animals (up to 66 mg g-1 dry wt after 12 months) than in the dietary loaded animals (approx. 34 mg g^-1 dry wt after 24 months). This study yielded hepatic iron concentrations comparable to those seen in human thalassaemia patients with comparative low hepatotoxicity. Splenic iron concentrations in the parenteral iron loaded group generally exceeded those reported in thalassaemia. Iron concentrations derived from computer assisted morphometry of liver iron deposits correlated well ( r = 0.88, p < 0.001) with chemical analysis data. The fraction of iron in the non-parenchymal cells correlated positively with the duration of iron loading (r = 0.86, p < 0.001).     

Uptake and distribution of cadmium in maize inbred lines

Genotypic variation in uptake and distribution of cadmium (Cd) was studied in 19 inbred lines of maize (Zea mays L.). The inbred lines were grown for 27 days on an in situ Cd-contaminated sandy soil or for 20 days on nutrient solution culture with 10 µg Cd L^-1. The Cd concentrations in the shoots showed large genotypic variation, ranging from 0.9 to 9.9 µg g^-1 dry wt. for the Cd-contaminated soil and from 2.5 to 56.9 µg g^-1 dry wt. for the nutrient solution culture. The inbred lines showed a similar ranking for the Cd concentrations in the shoots for both growth media (r²=0.89). Two main groups of inbreds were distinguished: a group with low shoot, but high root Cd concentrations (shoot: 7.4±5.3 µg g^-1 dry wt.; root: 206.0±71.2 µg g^-1 dry wt.; shoot Cd excluder) and a group with similar shoot and root Cd concentrations (shoot: 54.2±3.4 µg g^-1 dry wt.; root: 75.6±11.2 µg g^-1 dry wt.; non-shoot Cd excluder). The classification of the maize inbred lines and the near equal whole-plant Cd uptake between the two groups demonstrates that internal distribution rather than uptake is causing the genotypic differences in shoot Cd concentration of maize inbred lines. Zinc (Zn), a micronutrient chemically related to Cd, showed an almost similar distribution pattern for all maize inbred lines. The discrepancy in the internal distribution between Cd and Zn emphasizes the specificity of the Cd distribution in maize inbred lines.     

Seasonal variations in nitrate content,total nitrogen,and nitrate reductase activities of macrophytes from a chalk stream in Upper Bavaria

Summary 11 macrophytic species from a groundwater influenced chalk stream in Upper Bavaria were investigated during a period of one year in order to determine differences in the endogenous nitrate content, in total nitrogen content and in nitrate reductase activity (NRA). Nitrate concentrations of different plants taken from the same site of the river varied by a factor of approximately 10³. A maximum of 1,958 mol NO ₃ ^- g^-1 dry w. could be measured in the petioles of Nasturtium officinale, which accounts for 12% of plant dry w. Very high values were also found in Callitriche obtusangula and Veronica angallis-aquatica. In comparison to the ambient water, mean accumulation rates of up to 131 could be found. In Fontinalis antipyretica, the plant poorest in nitrate, the ratio was only 1.24:1. Elodea canadensis belonged to a group of plants having very low nitrate concentrations. Since NRA was very low too, it is assumed that nitrogen nutrition of this species depends rather on ammonia than on nitrate. With a few exceptions nitrate content of different plant organs varied markedly. In general they were lowest in leaves and highest in shoot axes. Appreciable amounts of nitrate were also found in the roots of plants. No correlation could be found between endogenous nitrate content and NRA. In contrast to endogenous nitrate content and NRA, total nitrogen concentrations of the plants did not differ significantly.     

Astragaloside IV and polysaccharide production by hairy roots of Astragalus membranaceus in bioreactors

Hairy roots of Astragalus membranaceus were grown in bioreactors up to 30 l for 20 d. Cultures from a 30 l airlift bioreactor gave 11.5 g l dry wt with 1.4 mg g^–1 astragaloside IV, similar to cultures from 250 ml and 1 l flasks, but greater than yields from a 10 l bioreactor (dry wt 9.4 g l^–1, astragaloside IV 0.9 mg g^–1). Polysaccharide yields were similar amongst the different bioreactors (range 25–32 mg g^–1). The active constituent content of the cells approached that of plant extracts, indicating that large scale hairy root cultures of A. membranaceus has the potential to provide an alternative to plant crops without compromising yield or pharmacological potential.     

Improvement of phenylethanoid glycosides production by a fungal elicitor in cell suspension culture of Cistanche deserticola

When, on the 15th day of growth, an elicitor from Fusarium solani was added at 40 mg l^–1 to Cistanche deserticola cell suspension cultures, the contents of echinacoside, acteoside and total phenylethanoid glycosides (PeGs) in cultured cells all increased over the next 27 d by over 100% to 15 mg g^–1 dry wt, 9 mg g^–1 dry wt and 57 mg g^–1 dry wt, respectively. The final biomass (1.3 mg dry wt ml^–1) was not affected.     

The effects of different external nitrate concentrations on growth of Phaseolus vulgaris cv. Seafarer at chilling temperatures

The effects of different applied nitrate concentrations (1 to 50 mol m³) on growth of Phaseolus vulgaris cv. Seafarer at temperatures around 15°C was examined. Total plant dry weight and carbon content decreased sharply with increased applied nitrate 1 to 10 mol m^-3 then decreased slightly with further increases in applied N. Total plant reduced -N content increased sharply with increased applied nitrate concentration from 1 to 5 mol m^-3, changed little with increased applied nitrate from 5 to 25 mol m^-3, then increased when applied nitrate was increased from 25 to 50 mol m^-3. Nitrate concentration in all tissues increased sharply with applied nitrate increased from 1 to 10 mol m³ and showed a further increase at 50 mol m³ applied nitrate. Fresh weight to dry weight ratio for all leaves and specific leaf area for all secondary leaves increased sharply with applied nitrate concentration from 1 to 5 mol m^-3 then decreased with applied nitrate 25 to 50 mol m³ Secondary leaf chlorophyll concentration decreased sharply when applied nitrate increased from 1 to 5 mol m^-3 but increased with applied nitrate from 25 to 50 mol m^-3. Initially, the rate of leaf extension was greater at 20 mol m^-3 applied nitrate than 1 mol m^-3 applied nitrate. It is proposed that decreased growth with increased applied nitrate in the range 1 to 10 mol m^-3 is due to increased leaf damage caused by a greater rate of leaf expansion.     

Boron induced changes in biochemical constituents,enzymatic activities,and growth performance of wheat

The present study investigates how excess boron (B) affects and alters the biochemical constituents and enzymatic activities of wheat (Triticum aestivum var. ‘Raj 4037’), consequently leading to reduced plant growth and yield. Plants were raised in soils supplemented with various concentrations of B (0, 1, 2, 4, 8, 16, and 32 µg B g^?1 soil). Biochemical constituents including soluble leaf protein contents, total phenol contents, soluble sugar contents, proline contents, enzymatic activities of peroxidase (POX), and nitrate reductase (NR) were analyzed. In addition, growth parameters namely shoot–root length, shoot–root fresh and dry weight, seed number and seed weight were analyzed to assess the impact of B toxicity. Results indicate that change in biochemical constituents were correlated with B treatments. Boron concentrations beyond 4 µg g^?1 significantly increased soluble leaf protein contents, total phenol contents, soluble sugar contents, and proline contents. The POX activity was found to be positively correlated with B treatments. B significantly affects nitrogen metabolism and nitrate accumulation which is reflected by the downregulation of NR activity at higher B concentrations. B induced changes in physiological parameters of the plant which subsequently led to the reduction in growth, biomass production, and yield attributes. Out of the various concentrations of B, 8 µg g^?1 was moderately toxic while 16 and 32 µg g^?1 generated high toxicity and induced B stress response to confer tolerance in wheat. Further, a possible mechanism of B toxicity response in wheat is suggested.     

The effect of explant origin and collection season on stilbene biosynthesis in cell cultures of Vitis amurensis Rupr.

Plant cell and tissue cultures are considered as a source of valuable secondary metabolites but usually produce insufficient level of the compounds, which is the limiting factor for their application in biotechnology. We obtained 18 callus cell cultures from different organs of wild grape Vitis amurensis Rupr. collected at different seasons and analyzed stilbene accumulation in combination with calli growth parameters. This analysis showed that temporal and tissue origin of the calli affected the rate of stilbene biosynthesis. Stem-derived calli accumulated higher stilbene levels and exhibited a higher expression of phenylalanine ammonia-lyase (PAL) and stilbene synthase (STS) genes than calli derived from the leaves and petioles. The highest content of stilbenes was detected in the calli initiated from grapevine stems collected in the autumn. In general, all “autumn” cell cultures contained more than 2 mg g^??1 dry wt (up to 11 mg g^??1 dry wt) and exhibited high PAL and STS genes expression in comparison with the calli initiated in the summer. The content of stilbenes in the “autumn” cell cultures were comparable to the highest stilbene contents detected in other plant sources described in the literature. Thus, selecting the most optimal explant source for cell culture establishment could be an effective approach towards developing plant cell cultures producing high stilbene levels.

     

Growth, water use efficiency, and proline content of hydroponically grown tomato plants as affected by nitrogen source and nutrient concentration

Tomato plants (Lycopersicon esculentum Mill. cv. Counter) were grown in 12-L polyethylene containers in aerated and CaCO₃-buffered nutrient solutions containing different concentrations of complete stock solutions with either nitrate (stock solution N) or ammonium (stock solution A) as the only nitrogen source (X1 = standard concentration with 5 mM NO₃ ^–-N or NH₄ ⁺-N, and X3, X5.5, X8 and X11 = 3, 5.5, 8, 11 times the standard concentration), or a mixture of both stock solutions (N:A ratio = 100:0, 75:25, 50:50, 25:75, 0:100) at moderate nutrient concentration (X3). Total dry matter production and fruit dry weight were only slightly affected by increasing nutrient concentration if nitrate was supplied as the sole nitrogen source. Compared to nitrate, ammonium nitrogen caused a decrease in total dry weight (32–86% between X1 and X11), but led to an increase in both total dry weight and fruit dry weight (11% and 30%) at low concentration if supplied in addition to nitrate nitrogen (N:A ratio = 75:25). Dry matter partitioning in plants was affected by the strength of the nutrient solution, but even more by ammonium nitrogen. Fruits accumulated relatively less dry matter than did the vegetative parts of tomato plants when supplied with nutrient solutions containing ammonium as the only nitrogen source (fruit dry weight to total dry weight ratio 0.37 and 0.15 at low and high nutrient concentration), while nitrate nitrogen rather supported an increase in dry matter accumulation in the reproductive organs (fruit dry weight to total dry weight ratio 0.39–0.46). The water use efficiency (WUE) was only slightly affected by the strength of the nutrient solutions containing nitrate nitrogen (2.9–3.4 g DW (kg H₂O)^–1), while ammonium nitrogen led to a decrease in WUE from 2.4 to 1.3 g DW (kg H₂O)^–1at low (X1) and high (X11) nutrient concentration, respectively. The proline content of leaves fluctuated (0.1–5.0 mol (g fresh weight)^–1) according to nutrient concentration and global radiation, and reflected enhanced sensitivity of plants to these potential stress factors if ammonium was the predominant N source supplied. It was concluded, that proline is a reliable indicator of the environmental stress imposed on hydroponically grown tomato plants.     

Net Accumulation of Minerals and Water and the Carbon Budget in an Expanding Leaf of Tomato

The changes in f. wt, d. wt, nitrogen, potassium, calcium, phosphorus,magnesium and carbon of the seventh leaf of a tomato plant weremeasured at seven occasions from 10 days to 30 days after leafemergence. Measurements of CO₂ exchange by the leaf during bothlight (70 W m^–2, 7 h) and dark (17 h) periods and thechange in carbon content over these two periods enabled a carbonbalance to be constructed on these seven occasions. Changesin the sugars and starch contents of the leaf over these twoperiods at each occasion were measured. With the exception of calcium the rates of accumulation of allsubstances increased to their maxima when the leaf was 22–24-days-old.Carbon fixation per unit f. wt. increased to a maximum whenthe leaf was 16-days-old. In a 10-day-old leaf the rate of carbonfixation was already four-fifths of maximum and one-quartermore than that at 30 days. The rate of night respiratory lossof carbon per unit fresh weight decreased as the leaf expanded.In a 10-day-old leaf, the amount of carbon lost by night respirationaccounted for one-quarter of that fixed in the same day. Thisfraction fell to one-tenth when the leaf was 22-days-old andremained constant thereafter. The amount of carbon being importedto the leaflets of a 10-day-old leaf was less than one-quarterof that accumulated in 1 day. Thus, the contribution of theimported carbon to the leaf growth up to this stage is relativelysmall. The transition of the seventh leaf from being a net importerto being a net exporter occurred when the leaf was 13-days-old. The sucrose content per unit f. wt was higher in the youngerthan in the older leaves and was not correlated to the transitionfrom net import to net export. The accumulation and breakdownof starch in a leaf were related not only to the growth of theleaf but also to the development of the whole plant. Lycopersicon esculentum, tomato, leaf, accumulation of minerals, water content, carbon budget     

Etudein situ de l'influence de l'humidité et de la teneur en nitrate d'un sol dunaire sur l'accumulation et la réduction du nitrate chez l'oyat (Ammophila arenaria L.)

Résumé L'étude du fonctionnement du cycle de l'azote dans les milieux dunaires des c?tes méditerranéennes fran?aises a conduit à analyser le comportement de l'oyat,Ammophila arenaria, au cours de son développement en réponse aux variations de l'humidité et de la teneur en nitrate du sol. Les mesures d'activité nitrate réductase et de la teneur en nitrate dans les feuilles ont été effectuées simultanément avec les mesures des teneurs en eau et en nitrate du sol. Cette plante a des activités nitrate réductase ne dépassant pas 0,27 μmoles h⁻¹ g⁻¹ matière fra?che, qui n'ont pu être mesuréesin vivo qu'en présence de nitrate exogène dans le milieu d'incubation. Il appara?t que la plante réduit ou accumule préférentiellement le nitrate selon que l'on se situe en période humide ou sèche. Pour des valeurs voisines ou inférieures à 2% d'humidité dans les vingt premiers centimètres de sol, l'activité nitrate réductase décro?t et des quantités importantes de nitrate s'accumulent (169 μg N.NO₃.g⁻¹ matière sèche). Dans ces conditions, le nitrate dans la solution du sol peut atteindre une concentration élevée (6 meq.l⁻¹). Inversement, au-delà de 2% d'humidité le nitrate endogène s'épuise et l'activité nitrate réductase augmente. La régulation de l'assimilation et de l'accumulation du nitrate par l'oyat dépend de son alimentation hydrique et done des quantités de nitrate absorbées à partir de la solution du sol et véhiculées dans la sève brute.

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In situ study of the influence of dune soil humidity and nitrate contents on the nitrate accumulation and reduction in marram (Ammophila arenaria L.)

Summary The search for a better understanding of the nitrogen cycle in the sand dunes of french mediterranean beaches have driven us to study the habits ofAmmophila arenaria. In this way, we have followed its responses to different soil water potentials and nitrate contents of the soil during its development. Nitrate reductase activities and nitrate contents of leaves have been measured simultaneously with water and nitrate contents of soil. This plant has a slight nitrate reduction activity, not more than 0,27 μmoles h⁻¹ g⁻¹ fresh matter, which could be measuredin vivo only by the addition of nitrate to the incubation media. It seems that the plant reduces or else it stores, in a preferential way the nitrate whether it is in a humid or dry period. If humidity values are near or below 2%, the marram diminishes its assimilation activity and stores important amounts of nitrate (169 μg N−NO₃ ⁻.g⁻¹ dry matter). In these conditions the nitrate can be highly concentrated in the soil solutions (6 meq.l⁻¹). Opposite, above 2% of humidity, the nitrate reductase activity decreases and the endogenous nitrate is consumed. The regulation of the assimilation and storage of nitrate by the marram is mainly a function of the soil humidity and so, of the amount of nitrate taken from the soil solution and carried into the xylem.

     

Abscisic acid and gibberellin-like substances in roots and root nodules ofGlycine max

Summary The content of endogenous gibberellin (GA)-like substances of roots and root nodules of SOya, and GA production byRhizobium japonicum cultures, were investigated by a combined thin layer chromatographic (TLC)-dwarf pea epicotyl bioassay technique. GAs were more concentrated in root nodules than in the roots, totalling 1.34 and 0.16 nM GA₃ equivalents g⁻¹ dry wt. respectively. GA production byR. japonicum cultures was demonstrated (1.00 nM GA₃ equivalentsl ⁻¹) and comparison of the GA components of plant and bacterial culture medium extracts, suggested that rhizobial GA production may contribute to the nodule GA content. Cis-trans abscisic acid (ABA) was identified in root and nodule extracts by TLC-gas liquid chromatography (GLC), and amounted to 0.18 and 2.21 nM g⁻¹ dry wt. respectively, whereas 0.30 and 4.63 nM ABA equivalents g⁻¹ dry wt. were detected by a TLC-wheat embryo bioassay technique. ABA was not detected in extracts of bacterial cultures.     

Variation in huperzine A and B in Australasian Huperzia species

Huperzine A (HupA) and huperzine B (HupB) are alkaloids with acetylcholine esterase inhibitory activity and potential applications in the treatment of Alzheimer's disease. Both alkaloids were isolated in the 1980s from the Chinese lycopod Huperzia serrata (Thunb. ex Murray) Trevis., which has been used since the Tang dynasty as a traditional Chinese medicine. Most of the HupA currently used in herbal supplements and medicines worldwide is sourced from H. serrata which on average contains only 0.18 mg g⁻¹ dry wt HupA and is experiencing a rapid decline in China due to over-harvesting. Eleven Australasian Huperzia species were surveyed and nine species were found to contain both alkaloids, with a significant positive relationship observed between HupA and the lower abundance HupB. An Australian Huperzia carinata plant had one of the highest HupA concentrations recorded for a plant (1.03 mg g⁻¹ dry wt) and an Huperzia phlegmaria plant had the highest HupB value of all species surveyed (0.23 mg g⁻¹ dry wt). Intra-specific variation in huperzine concentration was examined for H. phlegmaria and Huperzia phlegmarioides and both HupA and HupB varied substantially within each species, but this variation was unrelated to foliar nitrogen levels.     

Production of medium chain length polyhydroxyalkanoates by fed-batch culture of Pseudomonas oleovorans

Pseudomonas oleovorans was cultivated to produce medium chain length polyhydroxyalkanoates (MCL-PHAs) from octanoic acid and ammonium nitrate as carbon and nitrogen source, respectively, by a pH-stat fed-batch culture technique. The octanoate in the culture broth was maintained below 4 g l^–1 by feeding the mixture of octanoic acid and ammonium nitrate when the culture pH rose above 7.1. The final cell concentrations of 63, 55 and 9.5 g l^–1, PHA contents of 62, 75 and 67% of dry cell wt, and productivities of 1, 0.63 and 0.16 g l^–1 h^–1 were obtained when the C/N ratios in the feed were 10, 20 and 100 g octanoic acid g^–1 ammonium nitrate, respectively.     

SEASONAL FLUCTUATIONS IN TISSUE NITROGEN FOR FIVE SPECIES OF PERENNIAL MACROALGAE IN RHODE ISLAND SOUND1

Tissue nitrogen was assessed monthly for 16 months in five species of perennial macroalgae representing three phyla at one location in Rhode Island Sound. The species showed a remarkable similarity in their pattern of seasonal fluctuation in both nitrate and total nitrogen. The period of greatest accumulation (January through March) coincided with the period of highest concentration of inorganic nitrogen in the water, and for most of these algae it was also the time of-least growth. Conversely, the period of lowest tissue nitrogen (50% of the winter value, May through July) coincided with the period of lowest inorganic nitrogen in the water and highest algal growth. The greatest accumulation of nitrate was found in Laminaria saccharina (L.) Lamour. (80 μmol·g dry wt.^?1), four times as much as that measured simultaneously in the other species and 560 times the ambient concentration. By April the concentration of internal nitrate had dropped to nearly undetectable levels, but in August it began to accumulate again—a pattern that was repeated in Chondrus crispus Stackh. In Ascophyllum nodosum (L.) Le Jolis, Fucus vesiculosus L. and Codium fragile subsp. tomentosoides (Van Goor) Silva, the period of negligible internal nitrate level extended from March to December. The greatest concentration of total tissue nitrogen was measured in C. crispus (4.8% dry wt.), double the maximum in L. saccharina (2.3% dry wt.).     

Body Mass Parameters,Lipid Profiles and Protein Contents of Zebrafish Embryos and Effects of 2,4-Dinitrophenol Exposure

Morphology and physiology of fish embryos undergo dramatic changes during their development until the onset of feeding, supplied only by endogenous yolk reserves. For obtaining an insight how these restructuring processes are reflected by body mass related parameters, dry weights (dw), contents of the elements carbon and nitrogen and lipid and protein levels were quantified in different stages within the first four days of embryo development of the zebrafish (Danio rerio). The data show age dependent changes in tissue composition. Dry weights decreased significantly from 79μgdw/egg at 0hours post fertilization (hpf) to 61 μgdw/egg after 96 hpf. The amounts of total carbon fluctuated between 460 mg g^-1 and 540 mg g^-1 dw, nitrogen was at about 100 mg g^-1 dw and total fatty acids were between 48–73 mg g^-1 dw. In contrast to these parameters that remained relatively constant, the protein content, which was 240 mg g^-1 at 0 hpf, showed an overall increase of about 40%. Comparisons of intact eggs and dechorionated embryos at stages prior to hatching (24, 30, 48 hpf) showed that the differences seen for dry weight and for carbon and nitrogen contents became smaller at more advanced stages, consistent with transition of material from the chorion to embryo tissue. Further, we determined the effect of 2,4-dinitrophenol at a subacutely toxic concentration (14 μM, LC10) as a model chemical challenge on the examined body mass related parameters. The compound caused significant decreases in phospholipid and glycolipid fatty acid contents along with a decrease in the phospholipid fatty acid unsaturation index. No major changes were observed for the other examined parameters. Lipidomic studies as performed here may thus be useful for determining subacute effects of lipophilic organic compounds on lipid metabolism and on cellular membranes of zebrafish embryos.