Autotrophe Gewebekulturen von Ruta graveolens und deren 14CO2-Markierungsprodukte

Summary It is possible to obtain autotrophic callus cultures by inhibiting cell respiration. During a first passage of four weeks the cultures synthesized chlorophyll on an agar-medium with a minimum of organic substances such as sugar, amino acids and vitamins. In the second passage these cultures were kept on the same medium but were aerated with a mixture of 99% N₂ and 1% CO₂. In the third and last passage the medium contained only mineral substances and the same mixture of N₂ and CO₂ was used for aeration. This pure mineral medium was supplemented with the Hoagland's solution.These autotrophic callus cultures were grown for about two years under these conditions and showed a growth quotient of ten.Three different groups of tissues were taken for the ¹⁴CO₂-fixation. The first group was grown for four weeks on a heterotrophic medium and aerated with O₂. This is the socalled respirating group. The second and third group were both aerated with the mixture of N₂/CO₂ but they were grown on different mediums. One of these groups was grown on a heterotrophic medium for four weeks: these are heterotrophic photosynthesizing tissues. The third group was grown on a pure mineral medium, and these are the autotrophic photosynthesizing callus tissues.Respirating tissues are different from photosynthesizing cultures in respect to the quantity of light-induced CO₂-fixation.The thin-layer chromatograms reveal the difference between heterotrophic and autotrophic tissues. In the light dependent ¹⁴CO₂-incorporation the difference is in the amounts of the labelled amino acids glycine and serine. In the dark dependent incorporation the difference is found in the amount of the labelled amino acid aspartic acid. The more autotrophic these tissues are, the higher the level of the CO₂-fixation in these amino acids is.

---

---

Mit Hilfe der Deutschen Forschungsgemeinschaft.     

High photosynthetic photon flux and high CO2 concentration under increased number of air exchanges promote growth and photosynthesis of four kinds of orchid plantlets in vitro

Summary In vitro plantlets of Phalaenopsis ‘Happy Valentine’, Neofinetia falcate Hu, Cymbidium kanran Makino, and Cymbidium goeringii Reichb. f. were grown under photoautotrophic [high photosynthetic photon flux (PPF), high CO₂ concentration, and increased number of air exchanges] and heterotrophic (low PPF, low CO₂ concentration, no air exchanges) culture conditions. After 40 d of culture, a significant difference in plantlet growth was observed between the two cultures. Total fresh and dry mass were on average 1.5 times greater in photoautotrophic culture than in heterotrophic culture. Higher net photosynthetic rates were also observed for Phalaenopsis in photoautotrophic culture. In photoautotrophic culture, little difference was observed in air temperature between the inside and outside of the culture vessel, whereas in heterotrophic culture, air temperature inside the culture vessel was 1–2°C higher than that outside the culture vessel. Relative humidity inside the culture vessel was remarkably different between the two cultures: 83–85% in photoautotrophic culture and 97–99% in heterotrophic culture. These results indicated that growth and net photosynthetic rate of in vitro orchid plantlets were susceptible to the culture environments such as PPF, CO₂ concentration, relative humidity (RH), and the number of air exchanges, which would allow a more efficient micropropagation system for these orchid plants.     

Effect of varying co2 and light levels on growth of hedyotis and sugarcane shoot cultures

Summary Shoot cultures of Hedyotis corymbosa, a C3 species, and sugarcane, a C4 species, were used to examine the effects of various CO₂ concentrations and two light intensities on growth and photosynthetic rates. The fresh and dry weights of new growth of Hedyotis shoots were higher when grown under the higher light intensity, while differences among shoots grown under different CO₂ levels were marginal. After 14 d of growth in various CO₂ concentrations, no significant differences could be observed in the newly produced leaves of Hedyotis with respect to stomatal distribution and number of mesophyll cell layers. Shoots grown under high light intensity did not show higher rates of photosynthesis than those grown under low light intensity. Also, sugarcane shoots grown in a CO₂-enriched environment did not have higher photosynthetic rates, perhaps because the C4 pathway is less sensitive to the ambient CO₂ concentration. The quantum yield of Hedyotis shoots grown on medium with 20 g l⁻¹ sucrose was lower than that of shoots on lower sucrose concentrations, supporting the view that photosynthesis is inhibited by high levels of sucrose. Our results suggest that Hedyotis shoots in culture exhibit some form of acclimation to high CO₂. so that there is no net gain in productivity by photosynthesis.     

A culture method for microalgal forms using two-tier vessel providing carbon-dioxide environment: studies on growth and carotenoid production

A culture method was developed for photoautotrophic culture of Haematococcus pluvialis, Chlorella vulgaris, Scenedesmus obliquus, Spirulina platensis, Nostoc and Stigonema in a two-tier flask consisting of nutrient media in the upper chamber and CO₂ generating buffer mixture (KHCO₃/K₂CO₃) in the lower chamber. The concentration of buffer mixture was varied to obtain desired levels of CO₂. CO₂ at 2.0% (v/v) level enhanced growth and chlorophyll content over control cultures (without CO₂ supplementation) in all microalgal species. Haematococcus pluvialis culture in BBM and KM1 media showed 6.71- and 2.07-fold increase in biomass yields with astaxanthin productivity at 7.26 and 7.48 mg l^–1 level respectively. CO₂ supplementation to C. vulgaris and S. obliquus cultures resulted in 5.97- and 7.30-folds increase in biomass with 2–3 fold increase in chlorophyll and carotenoid contents over their respective controls. Similarly 2–3 fold increase in chlorophyll and carotenoid contents were observed in Sp. platensis, Nostoc and Stigonema spp. This culture methodology will provide information on CO₂ requirement for growth of algae and metabolite production and also facilitates studies on the influence of light and temperature conditions.     

CO2-Enrichment and photosynthetic photon flux affect the growth of in vitro-cultured apple plantlets

Micro-cuttings (shoots with two small leaves) of cultivar M9 apple were cultured in-vitro for 40 d under CO₂-enriched and non-enriched (i.e., ambient air) conditions, and at a PPF of 40 or 100 μmol m^-2 s^-1 Afterward, shoot length, number of leaves, leaf area, chlorophyll content, shoot and root fresh weights, and % survival were recorded. Those plant-lets grown under CO₂- and PPF-enriched treatments were healthy and vigorous, and showed higher values for their growth parameters. In contrast, those grown without supplemental CO₂ or PPF often showed hyperhydricity. We also demonstrated that CO₂ enrichment and a relatively high PPF during in-vitro culture promoted normal photosynthesis and growth after ex-vitro transplantation.     

Photoautotrophic growth of cell suspension cultures fromChenopodium rubrum in an airlift fermenter

Summary This communication describes the construction and operation of an airlift fermenter for the photoautotrophic growth of cell suspension cultures fromChenopodium rubrum. The basic batch culture unit provides a culture of 1.51 volume, sufficient to permit frequent aseptic sampling. It can be maintained at any desired temperature and aerated to different extents. Using an initial cell density of about 400,000 cells per ml suspension, the increase in cell number is 270% after a 14 days' growth period, although the stationary phase of growth is not yet reached. The transfer of photoautotrophic cell suspensions fromChenopodium rubrum from stationary growth into the large volume of fresh culture medium in the airlift fermenter results in an immediate protein formation, followed by an exponential phase of cell division, whereas rapid chlorophyll accumulation is delayed by 2 days.The growth capacities of photoautotrophic fermenter cultures including protein and chlorophyll formation as well asin vitro activities of the ribulosebisphosphate carboxylase and the phosphoenolpyruvate carboxylase are greatly lower as compared to photoautotrophic cells propagated in standard two-tier culture vessels using 30 ml culture medium. However the pattern of change in the activities of carboxylation enzymes is quite similar in both culture systems.Photoautotrophic cell suspensions fromChenopodium rubrum grown in an airlift fermenter assimilate about 90 mol CO₂/mg chlorophyll × hour. Dark CO₂ fixation is about 1.5% of the light values.Abbreviations PEF phosphoenolpyruvate - RuDP ribulosebisphosPhate - NS ground glass joints of standardized size made from Duran glass, Schott, Germany     

Analysis of ultrastructure and reactive oxygen species of hyperhydric garlic (Allium sativum L.) shoots

Hyperhydricity is a physiological disorder frequently affecting shoots propagated in vitro. Since it negatively affects shoot multiplication vigor, and impedes the successful transfer of micropropagated plants to in vivo conditions, hyperhydricity is a major problem in plant tissue culture. In commercial plant micropropagation, there are reports of up to 60% of cultured shoots or plantlets which demonstrate hyperhydricity, which reflects the pervasiveness of this problem. The phenomenon has been correlated to water availability, microelements, and/or hormonal imbalance in the tissue culture. In this study, the ultrastructure and the characteristics of reactive oxygen species between hyperhydric and normal shoots of garlic were studied. We observed that in some cells of hyperhydric tissues, the intranuclear inclusion was separated, the mitochondrion was swollen and its intracristae had splits, the organelles were compressed against the cell wall, and the chloroplasts and intergranal thylakoids were also compressed. Additionally, the content of chlorophyll and soluble protein in hyperhydric shoots decreased significantly. For instance, chlorophyll a decreased 43.61%, chlorophyll b decreased 49.29%, chlorophyll a+b decreased 48.10%, and soluble protein dropped 47.36%. In contrast, the O₂ generation rate and H₂O₂ level increased 45.36% and 63.98%, respectively, obviously higher than the normal shoots. Lipoxygenase activity and malondialdehyde content in the hyperhydric shoots increased significantly, while the electrolyte leakage rose, indicating a serious membrane lipid peroxidatic reaction. Superoxide dismutase, peroxidase, catalase, glutathione peroxidase, and ascorbate peroxidase activities in hyperhydric tissue were all significantly higher than in normal leaf tissue. The antioxidant metabolism demostrated a close connection between hyperhydricity and reactivated oxygen species.     

CO2 Dynamics and Growth in Photoautotrophic and Photomixotrophic Apple Cultures

The daily dynamics of CO₂ concentration in the culture vessels and the photoautotrophic or photomixotrophic growth capacity of apple (Malus pumila hybrid MM 106 paradisiaca× Northern Spy) cultures were studied. The photoautotrophic cultures were grown on a sugar-free growth medium and submitted (0S+CO₂) or not (0S-CO₂) to periodic injections of exogenous CO₂. The photomixotrophic cultures were grown in the presence of 30 g dm⁻³ sucrose, with (30S+CO₂) or without (30S-CO₂) CO₂ enrichment. The photosynthetic photon flux density applied was of 210 ± 5 μmol m⁻²s⁻¹. In the 0S-CO₂ treatment, CO₂ showed rather uniform and narrow light-dark fluctuations throughout the culturing cycle. In the 30S-CO₂ treatment, the daily ratio between CO₂ produced during the dark period and that uptaken during the following light period, was almost always above 1 with the only exception of a few days (from the 5^th to the 9^th day) when the amount of photosynthesised CO₂ was equal to or higher than that produced during dark respiration. The 0S+CO₂ cultures needed to be enriched all days with exogenous CO₂ to avoid periods of gas deficiency while in 30S+CO₂ the CO₂ injected the first culturing day was uptaken over 5 d; thereafter, daily injections were necessary. Culture fresh and dry mass, number of newly formed shoots and number of nodes per shoot in 0S+CO₂ treatment did not statistically differ from the values obtained with 30S−CO₂. The highest growth was observed in 30S+CO₂ treatment. The increase in culture fresh mass due to 1 μmol of CO₂ added to the culture vessels was 1.54 and 1.36 mg for 30S and 0S respectively, while in terms of dry mass the increase was about 2.5 times higher in the sugar-enriched treatment. CO₂ enrichment accounted for 77.3 % and 21.2 % of the final fresh mass in 0S+CO₂ and 30S+CO₂, respectively. This revised version was published online in July 2006 with corrections to the Cover Date.     

The effect of headspace renewal in a Temporary Immersion Bioreactor on plantain (Musa AAB) shoot proliferation and quality

The positive effect of ventilation of the culture container on in vitro shoot proliferation and quality was already proven for different species. Hereafter we report on the evolution of the headspace during in vitro culture of plantain in a Temporary Immersion Bioreactor (TIB) on the one hand, and culture on semi-solid medium on the other hand. The CO₂ and C₂H₄ concentration reached a maximum of 12% and 0.45 μl l⁻¹, respectively in the control treatment on semi-solid medium, compared to 5.7% CO₂ and 0.06 μl l⁻¹ C₂H₄ in TIB. The minimal O₂-concentration on semi-solid medium was 15.1%, compared to 19.3% in TIB. The multiplication rate was best in TIB, 6.4 compared to 4.3 in semi-solid conditions, and this was also the case for shoot height (4.3 cm compared to 3.3 cm), and leaf number (2.6 compared to 1.6). Moreover shoots produced on semi-solid medium showed distorted leaves. A typical day-night pattern in CO₂ and O₂ concentration was observed in TIB, as well as on semi-solid medium; this is illustrative for the photosynthetic capacity of the plant material produced in both systems.     

Photorespiratory toxicity in autotrophic cell cultures of a mutant of Nicotiana sylvestris lacking serine: glyoxylate aminotransferase activity

Procedures were devised for heterotrophic culture and autotrophic establishment of protoplast-derived cell cultures from the sat mutant of Nicotiana sylvestris Speg. et Comes lacking serine: glyoxylate aminotransferase (SGAT; EC 2.6.1.45) activity. Increasing photon flux rates (dark, 40, 80 mol quanta·m^-2·s^-1) enhanced the growth rate of autotrophic (no sucrose) wild-type (WT) cultures in air and 1% CO₂. Mutant cultures showed a similar response to light under conditions suppressing photorespiration (1% CO₂), and maintained 65% of WT chlorophyll levels. In normal air, however, sat cultures developed severe photorespiratory toxicity, displaying a negligible rate of growth and rapid loss of chlorophyll to levels below 1% of WT. Low levels of sucrose (0.3%) completely reversed photorespiratory toxicity of the mutant cells in air. Mutant cultures maintained 75% of WT chlorophyll levels in air, displayed light stimulation of growth, and fixed ¹⁴CO₂ at rates identical to WT. Autotrophic sat cultures accumulated serine to levels nearly nine-fold above that of WT cultures in air. Serine accumulated to similar levels in mixotrophic (0.3% sucrose) sat cultures in air, but had no deleterious effect on fixation of ¹⁴CO₂ or growth, indicating that high levels of serine are not toxic, and that toxicity of the sat mutation probably stems from depletion of intermediates of the Calvin cycle. Autotrophic sat cultures were employed in selection experiments designed to identify spontaneous reversions restoring the capacity for growth in air. From a population of 678 000 sat colonies, 23 plantlets were recovered in which sustained growth in air resulted from reacquisition of SGAT activity. Twenty-two had SGAT levels between 25 and 50% of WT, but one had less than 10% of WT SGAT activity, and eventually developed symptoms typical of the sat mutant. The utility of autotrophic sat cultures for selection of chloroplast mutations diminishing the oxygenase activity of ribulose-bisphosphate carboxylase/oxygenase (EC 4.1.1.39) is discussed.Abbreviations Chl chlorophyll - DW dry weight - FW fresh weight - SGAT Serine:glyoxylate aminotransferase - WT wild-type     

Effect of controlled carbon dioxide on in vitro shoot multiplication in Feronia limonia (L.) Swingle

The effect of controlled carbon dioxide environment on in vitro shoot growth and multiplication in Feronia limonia (a tropical fruit plant, Family- Rutaceae) was studied. Carbon dioxide available in the ambient air of the growth room was insufficient for in vitro growth of the shoots alone. Also, the presence of sucrose only as the C-source in the medium (without CO₂), was found to be inadequate for sustainable growth and multiplication of shoots. The carbon dioxide enrichment promoted shoot multiplication and overall growth. The promotory effect of CO₂ was independent of the presence of sucrose in the medium. In the presence of both CO₂ and sucrose, an additive effect was observed producing maximum shoot growth. In the absence of sucrose a higher concentration of CO₂ (10.0)g m⁻³ was required to achieve photoautotrophic shoot multiplication comparable to ambient air controls. Highest leaf area per shoot cluster promoting shoot growth and multiplication was recorded under this treatment. Shoots growing on sucrose containing medium under controlled CO₂ environment of 0.6 g m⁻³ concentration evoked better response than ambient air controls (shoots growing on sucrose containing medium) in growth room. This treatment produced the overall best response. The present study highlighted the possibility of photoautotrophic multiplication which might prove useful for successful hardening and acclimatization in tissue culture plants.     

Responses of strawberry plantlets cultured in vitro under superbright red and blue light-emitting diodes (LEDs)

Unrooted strawberry cv. `Akihime' shoots with three leaves obtained from standard mixotrophic cultures were cultured in the ``Culture Pack'-rockwool system with sugar-free MS medium under CO<sub>2</sub>-enriched condition. To examine the effect of superbright red and blue light-emitting diodes (LEDs) on in vitro growth of plantlets, these cultures were placed in an incubator, ``LED PACK', with either red LEDs, red LEDs1blue LEDs or blue LEDs light source. To clarify the optimum blue and red LED ratio, cultures were placed in ``LED PACK 3' under LED light source with either 100, 90, 80, or 70% red + 0, 10, 20, 30% blue, respectively, and also under standard heterotrophic conditions. To determine the effects of irradiation level, cultures were grown under 90% red LEDs + 10% blue LEDs at 45, 60 or 75 mol m^–2 s^–1 . Plantlet growth was best at 70% red + 30% blue LEDs. The optimal light intensity was 60 mol m^–2 s^–1. Growth after transfer to soil was also best after in vitro culture with plantlets produced were 70% red LEDs + 30% blue LEDs.     

Developmental and Photosynthetic Characteristics of a Photoautotrophic Chrysanthemum Culture

Chrysanthemum plantlets were cultivated in vitro on media with 2.0, 0.3, or 0 % sucrose, or photoautotrophically without an organic carbon source but with supplementation of the culture vessel atmosphere with 2 % CO₂. The photoautotrophically cultivated plantlets showed a better growth and multiplication, higher contents of chlorophyll (Chl) and carotenoids, higher Chl a/b ratio, net photosynthetic rate and ribulose-1,5-bisphosphate carboxylase/oxygenase and phosphoenolpyruvate carboxylase activities than plantlets grown on the medium with sucrose. This revised version was published online in June 2006 with corrections to the Cover Date.     

Enhanced Chlorella vulgaris Buitenzorg growth by photon flux density alteration in serial photobioreactors

Microalgae perform oxygenic photosynthesis and are capable of taking up a large amount of CO₂, using an inducible CO₂ concentrating mechanism (CCM), and fixing CO₂ into higher compounds. These characteristics make the microalgae potentially useful for removal and utilization of CO₂ emitted from industrial plants and, generally, the usage of photosynthetic microorganisms has increased and significantly improved as a solution for CO₂ emissions. In this light and based on previous research using Anabaena cylindrica IAM M1 and Spirulina platensis IAM M 135, enhancement was sought for CO₂ fixation and biomass production by Chlorella vulgaris Buitenzorg by increasing the photon flux density concurrent with increases in culture biomass during the cellular growth phase and was compared to cultures of Chlorella grown at optimal constant illumination, with all cultures grown using Bennick basal medium, 29°C, and a flow of 1.0 atm. 10% CO₂ enriched air delivered to three in serial photobioreactors of 0.200 dm³ capacity each. The results showed that increasing illumination during culture increased biomass production of Chlorella by ∼60% as well as increased CO₂ fixation ability by ∼7.0%. It was also demonstrated that the non-competitive inhibition of [HCO₃ ⁻] as a carbon source significantly affected the cultivation in both the increasing and constant photon flux density regimes.     

Effects of Acetazolamide (Diamox), Ethoxzolamide and High Levels of CO2 on Carbonic Anhydrase, Photosystem Activity, and Oxygen Evolution in Euglena gracilis

Investigations using steady-state culture conditions indicate that carbonic anhydrase activity is correlated to the photosynthetic rate in Euglena in some but not all circumstances. When cultures grown with 5% CO₂ were changed to air growth, the photosynthetic rate was independent of the carbonic anhydrase activity. While experiments using the inhibitor acetazolamide indicated a close correlation between photosynthetic capacity and carbonic anhydrase activity, the inhibitor was found to be nonspecific. Acetazolamide altered photosystem activities directly as measured by the photoreduction of DCPIP in chloroplast preparations, whole-cell fluorescence transients of chlorophyll a, and by whole chain photoelectron flow. Ethoxzolamide, another inhibitor of carbonic anhydrase, was also found to inhibit photosystem activities, i.e., the photoreduction of DCPIP, and in vivo photoelectron flow, at high concentrations. Cells grown in 5% CO₂ were less sensitive to the effects of acetazolamide than cells exposed to air. The rate of electron flow in chloroplasts from cells grown with 5% CO₂ and exposed to 10 mM acetazolamide was 2.5-fold faster than that of chloroplasts from air-grown cells exposed to the same concentration of inhibitor. The whole cell chlorophyll a fluorescence transients of cultures grown with high CO₂ were completely different from those of air-grown cells and also showed fewer effects on exposure to acetazolamide. These results suggest a reevaluation of the hypothesis that carbonic anhydrase activity regulates photosynthesis. It is also apparent that results from air-grown and 5% CO₂-grown cultures cannot be directly compared in such studies.     

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.     

Carbonic anhydrase,carbondioxide levels and growth of Nitrosomonas

The ammonia oxidizing bacterium Nitrosomonas europaea was grown either (a) with added bicarbonate in the absence of added CO₂ (bubbled through the culture), (b) with added bicarbonate plus low added CO₂ (0.03% v/v), or (c) without added bicarbonate with high added CO₂ (1% v/v). Cell doubling times of 12 h were observed in 1% cultures; doubling times of 2 to 3-fold longer wre found with 0.03% CO₂ and/or bicarbonate grown cultures. The specific activity of carbonic anhydrase was 40–80% lower in cultures grown on 1% CO₂. These results are compared with those in heterotrophic and photosynthetic microorganisms.Scientific Contribution Number 1241 from the New Hampshire Agricultural Experiment Station     

Evaluation of a closed system,diffusive and humidity-induced convective throughflow ventilation on the growth and physiology of cauliflower in vitro

The effects of ethylene inhibitors (silver nitrate – AgNO₃ and silver thiosulphate – Ag₂S₂O₃ as inhibitors of ethylene activity, cobalt chloride – CoCl₂ as inhibitor of ethylene biosynthesis) and ethylene stimulator (aminocyclopropane-1-carboxylic acid – ACC) were studied on the growth of cauliflower (Brassica oleracea L.) seedlings cultured in closed vessels (60 cm³). The addition of ethylene inhibitors have significant stimulatory effects on the growth and development of seedlings and the effects were greatest with 10 μM AgNO₃, the fresh weight of leaves was 2.6×, and the leaf area 2.8× those of the control (no additives). The effects of various methods of ventilation (humidity-induced convective through-flow ventilation, diffusive ventilation and sealed condition) on the growth and physiology of in vitrocauliflower seedlings were also investigated. The seedlings were cultured either in the presence or absence of AgNO₃ (inhibitors of ethylene activity) and ACC (a precursor). Ethylene and CO₂ levels in the head-space of the culture vessels were monitored. The humidity-induced through-flow ventilation system has shown to be effective for improving growth, leaf chlorophyll content and the rate of net photosynthesis and preventing symptoms of hyperhydricity, such as leaf epinasty, and franginess, reduction of leaf area etc. In contrast, the results also indicated that the sealing of culture vessels could have serious inhibitory effects on growth and development, induce hyperhydricity and reduce leaf chlorophyll content. In the light period, CO₂ depletion occurred in the head-space of the sealed vessels (ca. 40 μl l^-1), the CO₂ concentration increased with increasing efficiency of the ventilation. No ethylene accumulation was noticed in the head-space of the culture vessels when humidity-induced throughflow ventilation was applied; however, high ethylene accumulation occurred in sealed vessels. This revised version was published online in June 2006 with corrections to the Cover Date.     

CO2 and O2 gas exchange in outdoor thin-layer high density microalgal cultures

Two thin layer culture units operated as batch cultures with the algaChlorella kessleri were used in gas exchange experiments. The mass transfer coefficient K_g [g m^–2 h^–1 kPa^–1] of O₂ and CO₂ desorption from culture surface decreased with increasing culture temperature. Between 60–70% of supplied CO₂ was used for algal growth. It was estimated that the length of growth surface may be extended to about 50 m, without additional saturation by CO₂. On average 1.35 g CO₂ was consumed by the alga per 1 g of produced O₂. Net CO₂ consumption (R_CO2) and O₂ production (R_O2) were not inhibited by irradiance. R_O2 did not decrease (in some cases it even increased) along the culture surface, despite increased accumulation of O₂. Measurement of pO₂ where the culture leaves the reactor before being pumped back onto the illuminated surface, correlated with O₂ production and CO₂ consumption and may be used to monitor the reactors growth performance.     

Some morphogenic effects of sodium sulfate on tobacco callus

Callus cultures of Nicotiana tabacum L cv. Wisconsin 38 were initiated and grown on shoot-forming (SF) and callus proliferation (CP) medium with or without Na₂SO₄. Two cultures were maintained on SF medium with 0, 0.75, 1 or 1.5% Na₂SO₄ for 2.5 and 3.5 years. In the older culture only callus grown on salt formed shoots throughout the maintenance period, while in the younger culture the control responded best and Na₂SO₄ was inhibitory. Callus from the older culture which had been grown on salt continued to form shoots in the absence of salt. Na₂SO₄ caused adventitious shoot formation in three cultures on CP medium. These shoots were present for 7 subcultures after removal of Na₂SO₄; but established, control callus, did not form shoots when transferred to Na₂SO₄. Callus initiated and maintained on NaCl or mannitol showed a slight increase in shoot initiation. On NaCl, Na₂SO₄ or mannitol, the tissue osmotic potential became more negative and proline concentration increased.