Changes in Photosynthetic Characteristics Induced by Transferring Air-Grown Cells of Chlorococcum littorale to High-CO2 Conditions

When air-grown cells of Chlorococcum littorale was enrichedwith CO₂, growth was enhanced after a lag period of one to twodays at 20% CO₂, and 3 to 6 days at 40% CO₂. Changes in therate of photosynthesis measured as oxygen evolution and CO₂fixation, were similar to those observed for growth. Duringthe initial inhibition of photosynthesis in 40% CO₂, the activityof PSII was suppressed. In contrast, PSI activity was greatlyenhanced. Air-grown cells of C. littorale possessed comparatively highcarbonic anhydrase (CA) activity which was localized insidethe cells and on the cell surface. Under high CO₂ concentrationsextracellular CA activity was greatly suppressed and intracellularactivity almost completely abolished. Phosphoenol pyruvate carboxylaseactivity was also suppressed in high CO₂-grown cells. Ribulose-l,5-bisphosphatecarboxylase activity was higher in high-CO₂ grown cells thanin air-grown cells. The above results indicated that the lagphase induced by 40% CO₂ was due to suppression of PSII activity. ¹Part of this work was reported in the International PhotosynthesisCongress, Nagoya, 1992.     

Cloning and Characterization of High-CO2-Specific cDNAs from a Marine Microalga, Chlorococcum littorale, and Effect of CO2 Concentration and Iron Deficiency on the Gene Expression

Two cDNA clones exclusively induced under an extremely high-CO₂concentration (20%) were isolated from Chlorococcum littoraleby differential screening and named HCR (high-CO₂ response)1 and 2, respectively. The amino acid sequence of the proteinencoded by HCR2 exhibited homology to the gp91-phox protein,a critical component of a human phagocyte oxidoreductase, andto the yeast ferric reductases, Saccharomyces cerevisiae FRE1and FRE2 and Schizosaccharomyces pombe Frpl. The induction ofboth HCR mRNAs required extremely high-CO₂ conditions and irondeficiency, being suppressed under air conditions and by ironsufficiency, suggesting that the expression of these two HCRgenes required extremely high-CO₂ conditions and iron deficiencyin combination. The HCR2 protein was detected in the membranefractions of cells grown under conditions which would favorthe induction of HCR2-mRNA and the protein level was loweredwhen the cells were transferred from iron deficient to 10 µMFeSO₄ conditions (with 20% CO²). (Received September 10, 1997; Accepted November 14, 1997)     

Development of Vacuoles and Vacuolar H+-ATPase Activity under Extremely High CO2 Conditions in Chiorococcum littorale Cells

Abstract: The number and cross-sectional area of vacuoles in Chlorococcum littorale cells visualized with a differential interfer ence fluorescence microscope increased after their transfer from air to 40% CO₂. An immunological observation indicated that the level of subunit B of vacuolar H*ATPase also increased under 40% CO₂ conditions. The activity of nitrate-sensitive ATP-ase associated with the vacuolar membrane was 2–fold higher in 40% CO₂-_-grown cells than in air-grown cells. The effects of inhi bitors on the ATPase activity confirmed that these activities were derived from vacuolar-type H-ATPase. These results sug gest that vacuole development associated with that of vacuolar H⁺-ATPase occurred during the acclimatization of C. littorale cells to extremely high CO₂ conditions.     

Effect of Exogenous Siderophores on Iron Uptake Activity of Marine Bacteria under Iron-Limited Conditions

More than 60% of species examined from a total of 421 strains of heterotrophic marine bacteria which were isolated from marine sponges and seawater were observed to have no detectable siderophore production even when Fe(III) was present in the culture medium at a concentration of 1.0 pM. The growth of one such non-siderophore-producing strain, alpha proteobacterium V0210, was stimulated under iron-limited conditions with the addition of an isolated exogenous siderophore, N,N′-bis (2,3-dihydroxybenzoyl)-O-serylserine from a Vibrio sp. Growth was also stimulated by the addition of three exogenous siderophore extracts from siderophore-producing bacteria. Radioisotope studies using ⁵⁹Fe showed that the iron uptake ability of V0210 increased only with the addition of exogenous siderophores. Biosynthesis of a hydroxamate siderophore by V0210 was shown by paper electrophoresis and chemical assays for the detection of hydroxamates and catechols. An 85-kDa iron-regulated outer membrane protein was induced only under iron-limited conditions in the presence of exogenous siderophores. This is the first report of bacterial iron uptake through an induced siderophore in response to exogenous siderophores. Our results suggest that siderophores are necessary signaling compounds for growth and for iron uptake by some non-siderophore-producing marine bacteria under iron-limited conditions.     

Iron Deficiency-induced Increase of Root Branching Contributes to the Enhanced Root Ferric Chelate Reductase Activity

In various plant species, Fe deficiency increases lateral root branching. However, whether this morphological alteration contributes to the Fe deficiency-induced physiological responses still remains to be demonstrated. In the present research, we demonstrated that the lateral root development of red clover (Trifolium pretense L.) was significantly enhanced by Fe deficient treatment, and the total lateral root number correlated well with the Fe deficiency-induced ferric chelate reductase (FCR) activity. By analyzing the results from Dasgan et al. (2002), we also found that although the two tomato genotypes line227/1 (P1) and Roza (P2) and their reciprocal F1 hybrid lines ("P1 × P2" and "P2 × P1 ") were cultured under two different lower Fe conditions (10-6 and 10-7 M FeEDDHA), their FCR activities are significantly correlated with the lateral root number. More interestingly, the -Fe chlorosis tolerant ability of these four tomato lines displays similar trends with the lateral root density. Taking these results together, it was proposed that the Fe deficiency-induced increases of the lateral root should play an important role in resistance to Fe deficiency, which may act as harnesses of a useful trait for the selection and breeding of more Fe-efficiant crops among the genotypes that have evolved a Fe deficiency-induced Fe uptake system.     

重金属对绿球藻硝酸还原酶活性的影响

研究4种重金属离子(Cu2 、Cd2 、Zn2 、Pb2 )对绿球藻硝酸还原酶(NR)活性的影响。4种重金属离子的实验浓度分别为0.01、0.1、1、10、50、100、200 mg/L;0.1、1、5、10、50、100、200 mg/L;0.1、1、5、10、50、100、200 mg/L;0.1、1、10、50、100、200、400 mg/L,BG11培养基作对照。研究结果表明:Cu2 、Cd2 分别在低浓度0.01、0.1 mg/L时,便开始抑制硝酸还原酶活性,随着Cu2 、Cd2 浓度增加,抑制作用增强,酶活性逐渐降低;当Cu2 、Cd2 ≥10 mg/L时,NR活性检测不到。当Zn2 、Pb2 浓度分别低于0.1 mg/L和50 mg/L时,NR活性随着培养基中Zn2 、Pb2 浓度的增大逐渐增强;当Zn2 、Pb2 浓度分别大于0.1 mg/L和50 mg/L时,NR活性逐渐降低。结果提示:从4种重金属离子对NR活性的影响看,绿球藻对Zn2 、Pb2 耐受力高,特别是Pb2 ,而对Cu2 、Cd2 的耐受能力要低些。     

Azo Reductase Activity of Intact Saccharomyces cerevisiae Cells Is Dependent on the Fre1p Component of Plasma Membrane Ferric Reductase

Unspecific bacterial reduction of azo dyes is a process widely studied in correlation with the biological treatment of colored wastewaters, but the enzyme system associated with this bacterial capability has never been positively identified. Several ascomycete yeast strains display similar decolorizing behaviors. The yeast-mediated process requires an alternative carbon and energy source and is independent of previous exposure to the dyes. When substrate dyes are polar, their reduction is extracellular, strongly suggesting the involvement of an externally directed plasma membrane redox system. The present work demonstrates that, in Saccharomyces cerevisiae, the ferric reductase system participates in the extracellular reduction of azo dyes. The S. cerevisiae Δfre1 and Δfre1 Δfre2 mutant strains, but not the Δfre2 strain, showed much-reduced decolorizing capabilities. The FRE1 gene complemented the phenotype of S. cerevisiae Δfre1 cells, restoring the ability to grow in medium without externally added iron and to decolorize the dye, following a pattern similar to the one observed in the wild-type strain. These results suggest that under the conditions tested, Fre1p is a major component of the azo reductase activity.     

Nitrate Uptake and the Induction of Nitrate Reductase Activity in Wheat (Triticum aestivum L.) Seedlings

Nitrate uptake and the subsequent induction of in vivo nitratereductase activity in wheat were studied by investigating aeuploid and certain ditelosomic stocks which exhibited in vivoactivity significantly greater than that of the euploid. Thekinetics of nitrate uptake were investigated, but the high activitiesof the ditelosomics were not caused by increased uptake of nitrate,although ditelo-7B^L exhibited unusual uptake dynamics. Analysisof the induction of nitrate reductase activity revealed a biphasicgeneral pattern, with an initial rapid phase being followedby a slower but longer period of induction. The induction rateover the second period, although responsible for only a minorproportion of the total activity induced, was positively correlatedwith the final nitrate reductase level, unlike the rate overthe first induction period. Several stocks exhibited high inductionrates over one or other of the two phases, while ditelo- 1 A^sshowed an abnormal monophasic induction pattern. At the endof the second period of induction, nitrate reductase activitybecame more or less steady, except for activity fluctuationsassociated with the time of application of induction stimuli.     

Effects of chloramphenicol on photosynthesis, protein profiles and transketolase activity under extremely high CO2 concentration in an extremely-high-CO2-tolerant green microalga, Chlorococcum littorale

An extremely-high-CO2-tolerant alga, Chlorococcum littorale, showed high quantum efficiency of PSII (PhiII) in the light at 40% CO2, as well as at 5% CO2. However, PhiII decreased greatly when chloramphenicol (CAP) was added at 40% CO2, while no such decrease was observed at 5% CO2. Cycloheximide showed no effect on PhiII at either 5% or 40% CO2. The amount of a 76 kDa polypeptide (p76) on SDS-PAGE decreased markedly in the presence of CAP at 40% CO2 but not at 5% CO2. A partial amino acid sequence of p76 was 71-100% identical (10-14 identical residues out of 14 amino acids determined) to those of transketolases (TKLs) reported in higher plants and a cyanobacterium. In agreement with these observations, the TKL activity in C. littorale was decreased by CAP at 40% CO2, but not at 5% CO2. The transient decrease in TKL activity caused by CAP under 40% CO2 was well correlated with that in PhiII. These results indicate that the addition of CAP directly or indirectly influences the stability of TKL in C. littorale at 40% CO2, but not at 5% CO2, and that photosynthetic activity was reduced by a decrease in TKL activity.     

Time-course of Nitrate Uptake and Nitrate Reductase Activity in Nitrogen-depleted Dwarf Bean

The rate of nitrate uptake by N-depleted French dwarf bean (Phaseolus vulgaris L. cv. Witte Krombek) increased steadily during the first 6 h after addition of NO₃ -After this initial phase the rale remained constant for many hours. Detached root systems showed the same time-course of uptake as roots of intact plants. In vivo nitrate reductase activity (NRA) was assayed with or without exogenous NO₃^- in the incubation medium and the result ing activities were denoted potential and actual level, respectively. In roots the difference between actual and potential NRA disappeared within 15 min after addition of nitrate, and NRA increased for about 15 h. Both potential and actual NRA were initially very low. In leaves, however, potential NRA was initially very high and was not affected by ambient nitrate (0.1–5 mol m^-3) for about 10 h. Actual and potential leaf NRA became equal after the same period of time. In the course of nitrate nutrition, the two nitrate reductase activities in leaves were differentially inhibited by cycloheximide (3.6 mmol m^-3) and tungstate (1 mol m^-3). We suggest that initial potential NRA reflects the activity of pre-existing enzyme, whereas actual NRA depends on enzyme assembly during NO₃^- supply. Apparent induction of nitrate uptake and most (85%) of the actual in vivo NRA occurred in the root system during the first 6 h of nitrate utilization by dwarf bean.     

氰酸钾对Chlamydomonas reinhardii硝酸还原酶的诱导

单胞绿藻和高等植物一样通过硝酸还原酶(NAD(P)H-NR,EC 1,6.6.2)和亚硝酸还原酶(EC 1.7.7.1)同化硝酸盐(Florencio和Vega1982)。一般来说,硝酸盐是诱导NR活力所必需的。在某些情况下,6-RA等激素、NO_2~-、氯霉素、低pH、某些有机酸和含氮化合物和氮饥饿也     

Induction of nest building and spawning in Hoplosternum littorale

Sexually mature neotropical armoured catfish, Hoplosternum littorale were induced to build nests and spawn by reducing the conductivity of the water. Simulation of rain and increasing water level without a reduction in conductivity had no effect.     

Uptake and Metabolism of Iron Oxide Nanoparticles in Brain Cells

Magnetic iron oxide nanoparticles (IONPs) are used for various applications in biomedicine, for example as contrast agents in magnetic resonance imaging, for cell tracking and for anti-tumor treatment. However, IONPs are also known for their toxic effects on cells and tissues which are at least in part caused by iron-mediated radical formation and oxidative stress. The potential toxicity of IONPs is especially important concerning the use of IONPs for neurobiological applications as alterations in brain iron homeostasis are strongly connected with human neurodegenerative diseases. Since IONPs are able to enter the brain, potential adverse consequences of an exposure of brain cells to IONPs have to be considered. This article describes the pathways that allow IONPs to enter the brain and summarizes the current knowledge on the uptake, the metabolism and the toxicity of IONPs for the different types of brain cells in vitro and in vivo.     

Nitrate Reductase Activity: Phytochrome Mediation of Induction in Etiolated Peas

THE extractable activity of nitrate reductase from higher plant leaves is inducible by light and shows, under natural growth conditions, a pattern of diurnal variation¹. Studies on the nature of light involvement have generally used the green leaf as experimental material, implying that photosynthesis supports the induction process^1,2. We have examined the role of light for the induction of nitrate reductase activity in the etiolated terminal buds of field peas (Pisum arvense cv. Century). Treatments consisted of brief exposure of intact plants to broad bands of light, followed by a period in darkness before extraction for enzyme assay. These light treatments exclude the possibility of photosynthesis as a process contributing to induction. Under these conditions, induction is shown to be reversibly controlled by red and far red light, an effect ascribable to the pigment phytochrome.     

Iron Oxidation and Precipitation of Ferric Hydroxysulfates by Resting Thiobacillus ferrooxidans Cells

The oxidation of ferrous ions, in acid solution, by resting suspensions of Thiobacillus ferrooxidans produced sediments consisting of crystalline jarosites, amorphous ferric hydroxysulfates, or both. These products differed conspicuously in chemical composition and infrared spectra from precipitates formed by abiotic oxidation under similar conditions. The amorphous sediments, produced by bacterial oxidation, exhibited a distinctive fibroporous microstructure when examined by scanning electron microscopy. Infrared spectra indicated outer-sphere coordination of Fe(III) by sulfate ions, as well as inner-sphere coordination by water molecules and bridging hydroxo groups. In the presence of excess sulfate and appropriate monovalent cations, jarosites, instead of amorphous ferric hydroxysulfates, precipitated from bacterially oxidized iron solutions. It is proposed that the jarositic precipitates result from the conversion of outer-sphere (T_d) sulfate, present in a soluble polymeric Fe(III) complex, to inner-sphere (C_3v) bridging sulfate. The amorphous precipitates result from the further polymerization of hydroxo-linked iron octahedra and charge stabilized aggregation of the resulting iron complexes in solution. This view was supported by observations that bacterially oxidized iron solutions gave rise to either amorphous or jarositic sediments in response to ionic environments imposed after oxidation had been completed and the bacteria had been removed by filtration.