Competition between isoprene emission and pigment synthesis during leaf development in aspen

In growing leaves, lack of isoprene synthase (IspS) is considered responsible for delayed isoprene emission, but competition for dimethylallyl diphosphate (DMADP), the substrate for both isoprene synthesis and prenyltransferase reactions in photosynthetic pigment and phytohormone synthesis, can also play a role. We used a kinetic approach based on post‐illumination isoprene decay and modelling DMADP consumption to estimate in vivo kinetic characteristics of IspS and prenyltransferase reactions, and to determine the share of DMADP use by different processes through leaf development in Populus tremula. Pigment synthesis rate was also estimated from pigment accumulation data and distribution of DMADP use from isoprene emission changes due to alendronate, a selective inhibitor of prenyltransferases. Development of photosynthetic activity and pigment synthesis occurred with the greatest rate in 1‐ to 5‐day‐old leaves when isoprene emission was absent. Isoprene emission commenced on days 5 and 6 and increased simultaneously with slowing down of pigment synthesis. In vivo Michaelis–Menten constant (K_m) values obtained were 265 nmol m^?2 (20 μm ) for DMADP‐consuming prenyltransferase reactions and 2560 nmol m^?2 (190 μm ) for IspS. Thus, despite decelerating pigment synthesis reactions in maturing leaves, isoprene emission in young leaves was limited by both IspS activity and competition for DMADP by prenyltransferase reactions.     

Activity of a gene in transplanted oocytes in the annelid,Platynereis

Summary Pteridine eye pigment, indicative of the activity of theor ⁺-allele, was observed inor/or larvae ofPlatynereis, derived from transplantedor ⁺/or oocytes. These heterozygous oocytes had grown up inor/or hosts, themselves deficient in pteridine pigment synthesis. It is therefore concluded that theor ⁺ gene product, responsible for pteridine pigment synthesis in theor/or larvae, had been synthesized by the oocyte genomes.Supported by the Deutsche Forschungsgemeinschaft.     

Tyrosinase in the presumptive pigment cells of ascidian embryos: Tyrosine accessibility may initiate melanin synthesis

Tyrosinase activity appears in the presumptive pigment cells of ascidian embryos (Ciona intestinalis) several hours before the cells begin to synthesize melanin. These presumptive pigment cells develop into the otolith and ocellus pigment cells of the larval brain. Tyrosinase was identified by histochemical tests for tyrosine oxidase and dopa oxidase; both reactions were sensitive to tyrosinase inhibitors. Studies with puromycin suggested that tyrosinase was synthesized at the time it was first detected histochemically and that it was stable during the time interval before melanin synthesis. Supernumerary tyrosinase-containing cells were found adjacent to the presumptive pigment cells in three ascidian species examined (C. intestinalis, Styela partita, and Molgula manhattensis). Tyrosinase disappeared from the supernumerary pigment cells during larval development and these cells did not synthesize melanin.Tyrosinase in the presumptive and supernumerary pigment cells is apparently a functional enzyme which does not interact with substrate. External substrates ( -tyrosine and -dopa) did not react with enzyme in the living cells before the normal time of pigment synthesis, but gentle disruption of the cells (by freezing-and-thawing or osmotic shock) released active tyrosinase. Progessive enlargement of nonpigmented vesicles in the otolith cells of embryos exposed to phenylthiourea, an inhibitor of tyrosinase activity, suggested that tyrosinase vesicles actively accumulate tyrosine at the beginning of melanin synthesis. This tyrosine accumulation probably initiates melanin synthesis.     

Chloroperoxidase production by Caldariomyces fumago biofilms

Chloroperoxidase (CPO) is a versatile enzyme, which is secreted by the marine fungus Caldariomyces fumago (Leptoxyphium fumago). However, the application of the enzyme is hampered by its high price, which is due to the costly, labor‐intensive purification process. One challenge of the downstream process is the removal of a coproduced black pigment that forms a complex with the active enzyme. While strain development can be considered as an option to reduce the synthesis of the interfering pigment, the metabolism of the microorganism can be altered alternatively by using the biofilm growth mode of the fungus. The aim of this study was to reduce pigment formation during CPO synthesis. We investigated for the first time CPO production during C. fumago biofilm growth initiated through the presence of different microstructured stainless steel surfaces (material number: 1.4571; AISI 316Ti). CPO production by C. fumago was similar when grown as a biofilm or in suspension, whereas pigment formation was drastically reduced by cells grown on moderately structured surfaces (R_a = 0.13 ± 0.02 μm). The possibilities of biofilm growth for changing cell properties and for continuous fermentation are discussed.     

The Effect of Colored Light on Pigment Synthesis in Cultured Fern Leaf Primordia

The effect of white, blue, yellow, red and far-red light on the quantitative synthesis of the primary and auxilliary photosynthetic pigments in cultured leaf primordia of Osmunda cinnamomea L. is reported. The P₆₆₀ form of the now classical photoreceptor pigment system, phytochrome, has been demonstrated to be active in chlorophyll synthesis in cultured cinnamon fern leaf primordia as shown by red/far-red reversibility of chlorophyll synthesis. Also, it is apparent from the data presented that a blue absorbing pigment (P₄₂₀) is responsible for the extensive accumulation of chlorophylls and carotenoids in these cultured leaves.     

The Conditions for Bacteriochlorophyll Formation and the Ultrastructure of a Methanol-utilizing Bacterium,Protaminobacter ruber,Classified as Non-photosynthetic Bacteria

A methanol-utilizing bacterium, Protaminobacter ruber, formed a green pigment, when it was grown on 1,2-propanediol as a sole carbon and energy source. The pigment was identified as bacteriochlorophyll a by the absorption spectrum resembling the pigment from photosynthetic bacteria and by the exact stoichiometric relationship among the original pigment, the pigment treated to remove magnesium (bacteriopheophytin) and magnesium ion obtained from the pigment. Bacteriochlorophyll formation was stimulated by the exposure to light during the relatively early stage of the growth, while the continuous light exposure completely prevented the pigment formation. Aeration was also necessary for the pigment synthesis as well as the bacterial growth. Electron micrographs of thin section of P. ruber cells cultured in the intermittent light showed the probable existence of a chromatophore-like structure.     

Growth and pigment composition in the red alga <Emphasis Type="Italic">Halymenia floresii</Emphasis> cultured under different light qualities

Halymenia floresii is an edible species consumed in some Asian markets. In the Yucatan peninsula coast of Mexico, H. floresii dominates rocky substrata between 3 and 40 m where it grows up to 50 cm high. After analyzing the seasonal pattern of pigment content on H. floresii, we evaluate if and how the spectral composition of light affects growth and pigment dynamics under laboratory cultivation. Unialgal cultures were exposed to white, blue, red and green light in a 3-week experiment. Green light resulted in the highest algal growth rates. Synthesis of chlorophyll a, α-carotene and lutein, but not of β-carotene, was induced by white or green light. Phycocyanin synthesis was stimulated by blue light and phycoerythrin synthesis by blue or red light. Light quality treatments may be used to manipulate pigment composition in Halymenia floresii cultures.     

Isolation and screening of low-density polyethylene (LDPE) bags degrading bacteria from Addis Ababa municipal solid waste disposal site “Koshe”

Purpose

The present study aimed to explore the binding ability of acyl-CoA binding protein 2 to fatty acid acyl-CoA esters and its effect on Monascus pigment production in M. ruber CICC41233.

Methods

The Mracbp2 gene from M. ruber CICC41233 was cloned with a total DNA and cDNA as the templates through the polymerase chain reaction. The cDNA of the Mracbp2 gene fragment was ligated to expression vector pGEX-6P-1 to construct pGEX-MrACBP2, which was expressed in Escherichia coli BL21 to obtain the fusion protein GST-MrACBP2 and then measure the binding ability of fatty acid acyl-CoA esters. Additionally, the DNA of the Mracbp2 gene fragment was ligated to expression vector pNeo0380 to construct pNeo0380-MrACBP2, which was homologously over-expressed in M. ruber CICC41233 to evaluate Monascus pigment production and fatty acid.

Results

The cloned Mracbp2 gene of the DNA and cDNA sequence was 1525 bp and 1329 bp in length, respectively. The microscale thermophoresis binding assay revealed that the purified GST-MrACBP2 had the highest affinity for palmitoyl-CoA (Kd =70.57 nM). Further, the Mracbp2 gene was homologously overexpressed in M. ruber CICC41233, and a positive transformant M. ruber ACBP-E was isolated. In the Monascus pigments fermentation, the expression level of the Mracbp2 gene was increased by 1.74-fold after 2 days and 2.38-fold after 6 days. The palmitic acid content and biomass in M. ruber ACBP2-E were significantly lower than that in M. ruber CICC41233 on 2 days and 6 days. However, compared with M. ruber CICC41233, the yields of total pigment, ethanol-soluble pigment, and water-soluble pigment in M. ruber ACBP2-E increased by 63.61%, 71.61%, and 29.70%, respectively.

Conclusions

The purified fusion protein GST-MrACBP2 exhibited the highest affinity for palmitoyl-CoA. The Mracbp2 gene was overexpressed in M. ruber CICC41233, which resulted in a decrease in palmitic acid and an increase in Monascus pigments. Overall, the effect of MrACBP2 on the synthesis of fatty acid and Monascus pigment was explored. This paper explored the effect of MrACBP2 on the fatty acid synthesis and the synthesis of Monascus pigment. The results indicated the regulation of fatty acid synthesis could affect Monascus pigment synthesis, providing a novel strategy for improving the yield of Monascus pigment.

     

Untersuchungen über die lichtabhängige Carotinoidsynthese

Summary Under anaerobic conditions Fusarium aquaeductuum is able to synthesize carotenogenic enzymes but does not produce pigments. If illumination of the mycelia in the presence of oxygen is followed by an incubation in the dark under N₂ atmosphere, the strictly concurrent formation of the different carotenoids sets off as soon as aerobic conditions are restored. The paraboloidal increase of pigment production possibly indicates that synthesis of carotenogenic enzymes is also resumed. Blocking this enzyme synthesis by addition of cycloheximide leads to a simultaneous and linear increase of each carotenoid portion as soon as oxygen is replenished. This is interpreted to mean that light induces carotenogenic enzymes in a coupled group. On the other hand, our present and earlier results do not support any hypothesis on the existence of a carotenogenic multienzyme complex. The composition of the pigment after carotenoid production has ceased provides evidence for a selective inhibition of the synthesis of individual carotenogenic enzymes. Changes in pigment composition caused by an incubation of the mycelia for 12 h under anaerobic conditions are also reported.     

Betacyanin biosynthesis in the isolated hypocotyls bei Acetabularia mediterranea

Summary Isolated hypocotyls synthesize betacyanin after light exposure in Amaranthus caudatus L. Pigment synthesizing capacity is reduced in the hypocotyls with increased incubation of seedlings in dark after 24h. External feeding of precursors of betacyanin L-tyrosine and DOPA enhances pigment synthesis in the isolated hypocotyls to equal that of intact hypocotyls. Cotyledons are probably the source of precursors while both cotyledons and hypocotyls are the sites of betacyanin synthesis. Betacyanin synthesizing capacity is progressively lost from the base of the hypocotyl and precursors could not induce pigment synthesis in these regions.     

Effect of temperature on violacein production in a psychrotrophicChromobacterium from Lake Ontario sediment

A truly psychrotrophic strain ofChromobacterium, which was isolated from Lake Ontario sediment and characterized asChromobacterium lividum, was found to be capable of pigment production that was completely prevented at 0°C, although growth readily occurred. Normal pigment formation occurred at 15°C, 20°C, and 25°C. The prevention of synthesis of the pigment at 0°C, which was confirmed spectrophotometrically to be violacein, was not reversed by the presence of various carbon sources, although all except one acted as growth substrates. In addition, some of the carbon sources actually inhibited pigment production at 20°C, preventing violacein synthesis in the presence of pyruvate which was shown to allow pigmentation. Similar results were obtained under both liquid and solid media cultivation conditions.     

Leucine interference in the production of water-soluble red Monascus pigments

The formation of soluble Monascus red pigments is strongly positively and negatively regulated by different amino acids. Leucine, valine, lysine, and methionine had strong negative effects on pigment formation. Leucine supported poor pigment formation when used as sole nitrogen source in fermentations, yet it neither repressed pigment synthase(s) nor inhibited its action. The new pigments derived from the hydrophobic leucine were more hydrophilic than the conventional red pigments (lacking an amino acid side-chain) and were extracellularly produced. Therefore, the low level of red pigments produced when leucine was the nitrogen source was not due to feed-back regulation by cell-bound leucine pigments. The negative effect of leucine was caused by enhanced decay of pigment synthase(s). The enhanced decay was not due simply to de novo synthesis of a leucine-induced protease.Abbreviations mSG Monosodium glutamate - MOPS 3-(N-morpholine)propane sulfonic acid - DCW dry cell weight     

Negative effect of ammonium nitrate as nitrogen source on the production of water-soluble red pigments by Monascus sp.

Ammonium salts, especially ammonium nitrate, have been used as nitrogen sources for production of traditional water-insoluble Monascus pigments. However, we noted that defined media employing NH₄NO₃ as the sole nitrogen source in fermentations supported only poor pigment production by Monascus sp., and the pigments produced were mainly cell-bound. NH₄NO₃ was found not to (a) repress pigment synthase formation, (b) enhance synthase decay, or (c) serve as a nitrogen source for pigment production by resting cells; it had a weak inhibitory effect on the action of pigment synthase(s). The high level of cell-bound did not exert a feedback effect on the further synthesis of pigments. These observations indicate that the reason why NH₄NO₃ supports only low pigment production during fermentations is the poor ability of NH₄NO₃ to donate nitrogen in the Schiff-base reaction converting orange pigments to red ones.     

Heteroxanthin in Euglena gracilis

Summary 1. From a large scale preparation of Euglena gracilis, strain Z, besides the acetylenic pigments diatoxanthin and diadinoxanthin and the allene neoxanthin, an additional acetylenic xanthophyll has been isolated. 2. Mass and IR spectra and chemical reactions showed typical patterns of heteroxanthin from Vaucheria. 3. The pigment was transformed into diadinochrome-isomers with acidified acetone. 4. A partial synthesis of heteroxanthin from diadinoxanthin by LiAlH₄-reduction is described, confirming the structure proposed by Strain. 5. The identity of heteroxanthin with the trollein—like pigment described for Euglena is discussed.     

Die Hemmung der lichtinduzierten Chlorophyll-, Carotinoid- und Anthocyansynthese durch Äthanol

The Inhibition of the Light Induced Chlorophyll, Carotenoid and Anthocyan Synthesis by Ethanol. It is shown that already low concentrations of ethanol inhibit the light induced formation of pigments (chlorophylls, carotenoids, anthocyanins) in Raphanus-seedlings. The degree of inhibition depends on the ethanol concentration and rises with increasing incubation period. The inhibition of pigment synthesis is reversible, and immediately ceases when ethanol is removed. The formation of chlorophylls and anthocyanin is more repressed than that of carotenoids, and the formation of β-carotene to a higher extent than that of xanthophylls. It is concluded that ethanol inhibits pigment formation by inhibition of protein synthesis. These results indicate that ethanol and other lower alcohols cannot be used for the solubilizing of organic compounds when these are applied to plant tissues.     

Wirkungsspektren der Anthocyansynthese in Gewebekulturen und Keimlingen von Haplopappus gracilis

Summary The biosynthesis of anthocyanin in tissue cultures and intact seedlings of Haplopappus gracilis is a light-dependent reaction which can be induced by blue light only. Anthocyanin appeared in all organs of the seedling.Wounding of the plant led to an increase in the content of anthocyanin due to increased anthocyanin synthesis in the cotyledons.The action spectra of anthocyanin formation in tissue cultures and intact seedlings have two peaks, one at 438 nm and the other at 372 nm. The limit of activity in the direction of longer wavelengths lies between 474 and 493 nm. Red light of short and long wavelength is ineffective in the induction of pigment synthesis. The photoreceptor of the light reaction is supposed to be a yellow pigment (flavoprotein or carotinoid). In contrast to the intact plants, isolated cotyledons and wounded seedlings are able to form anthocyanin not only in the blue region but also during irradiation with red light of high intensity. The action spectrum of anthocyanin synthesis in the isolated cotyledons has a marked maximum at about 440 nm and a second one at about 660 nm. A little activity can be observed throughout the visible spectrum. The pigment synthesis induced by red light can be completely suppressed by DCMU, an inhibitor of photosynthesis. This indicates that in the case of the activity in the red light caused by wounding chlorophyll serves as photoreceptor.The anthocyanin synthesis in tissue cultures and seedlings could not be influenced by low energy radiation in the red or in the far red region, even after induction of anthocyanin synthesis by blue light of high intensity. Therefore it seems that the phytochrome system is not involved in anthocyanin synthesis in Haplopappus gracilis.     

Chloroplast autonomy in pigment synthesis

Summary An experimental design developed usingAcetabularia permits a novel approach to studies of cytoplasmic genetic functions. The site of the genes for the enzymes of the plastid pigment pathways were examined by 1. determining pigment content per cell and per chloroplast in intact cells and during long periods of enucleate cell growth, 2. comparing pigment synthetic activities of plastids isolated from intact and enucleate cells at various times postenucleation and 3. comparing the ability of intact and enucleate cells to modulate pigment content in response to various light regimens.Intact cells grow and increase their pigment content exponentially. Enucleate cells grow at the control rate for several weeks and increase their chloroplast number and pigment content proportionally. Pigment content per plastid remains constant in both intact and enucleate cells. Pigment synthesis in isolated chloroplasts from enucleate cells is normal up to 65 days post-enucleation when compared with isolated chloroplasts from intact control cells. Enucleate cells differentially modulate their pigment content in response to various light regimens in a manner indistinguishable from normal cells.The problems in interpreting these and other results are discussed and it is concluded that plastid autonomy in pigment synthesis is the simplest explanation.     

Induction of betacyanin formation in Chenopodium album cell cultures by co-cultivation with the duckweed Wolffia arrhiza

Cells of Chenopodium album and whole plants of the duckweed Wolffia arrhiza were cocultivated. In the presence of Wolffia arrhiza the synthesis of a red-violet pigment (betacyanin) was induced in several cells or cell clusters of Chenopodium album in the light. The exchange of solutes through the liquid phase was necessary for the induction of pigment formation. The red-violet cells could be selected and subcultivated resulting in a red callus. A reddish cell suspension was obtained in liquid culture in the presence of the duckweeds.Abbreviation 2 4-D (2,4-dichlorophenoxyacetic acid)