Experimental studies on the growth and usnic acid production in "lichen"Usnea ghattensis in vitro

The study was aimed to optimize the culture conditions for the production of usnic acid in the cultured cell aggregates composed of symbionts in lichen Usnea ghattensis in vitro. The cultured lichen tissue composed of symbionts appeared after about 2-3 weeks of inoculation in water-agar and malt-yeast extract (MYE) media and shown the production of usnic acid after 2-3 months of inoculation. However, the growth of symbionts was strongly affected by different culture conditions. The addition of excess carbon and nitrogen sources in the media has significantly enhanced the growth as well as usnic acid content. The cultured symbionts in MYE medium having 4% sucrose, 4% polyethyl glycol (PEG) gave 7.63 g dry biomass with 3.9 microg usnic acid/g dry biomass. In water-agar medium having 4% sucrose and 4% PEG gave 3.08 g dry biomass with 1.11 microg usnic acid/g dry biomass. The positive effects of medium on the growth of symbionts and the production of usnic acid are seemed to be due to nutritional factors.     

Oxidoreductases and cellulases in lichens: Possible roles in lichen biology and soil organic matter turnover

Lichens are symbiotic associations of a fungus (usually an Ascomycete) with green algae and/or a cyanobacterium. They dominate on 8 % of the world's land surface, mainly in Arctic and Antarctic regions, tundra, high mountain elevations and as components of dryland crusts. In many ecosystems, lichens are the pioneers on the bare rock or soil following disturbance, presumably because of their tolerance to desiccation and high temperature. Lichens have long been recognized as agents of mineral weathering and fine-earth stabilization. Being dominant biomass producers in extreme environments they contribute to primary accumulation of soil organic matter. However, biochemical role of lichens in soil processes is unknown. Our recent research has demonstrated that Peltigeralean lichens contain redox enzymes which in free-living fungi participate in lignocellulose degradation and humification. Thus lichen enzymes may catalyse formation and degradation of soil organic matter, particularly in high-stress communities dominated by lower plants. In the present review we synthesize recently published data on lichen phenol oxidases, peroxidases, and cellulases and discuss their possible roles in lichen physiology and soil organic matter transformations.     

The phenolic compounds in <Emphasis Type="Italic">Cladonia</Emphasis> lichens are not antimicrobial in soils

According to classic text books on lichen biology, the phenolic secondary chemicals in lichens have antibiotic effects on soil microorganisms and mycorrhizal fungi in ecosystems. However, the experimental evidence for this under natural conditions is still relatively scarce. We examined some of the assumptions behind the concept of antimicrobial effects of lichen secondary substances: (1) the secondary substances of Cladonia stellaris, usnic and perlatolic acids, are leached out from the lichens by rainwater; (2) these substances inhibit the microbial activity of soil, and; (3) since they are extremely resistant to microbial decomposition, the soil underneath a continuous lichen mat is enriched in usnic and perlatolic acids. Our results did not support any of these assumptions. The evidence for the antimicrobial activity of lichen secondary substances seems to be weak in comparison to other suggested functions such as light filtering and herbivore protection. We suggest that it is time to re-evaluate the evidence for the antimicrobial ecological role of lichen secondary substances in natural systems.     

The role of peroxidases in pistil-pollen interactions

Summary The majority of pistil peroxidases are involved in processes related to growth, development and senescence. Only the tissue specific peroxidases in the transmitting tissue of the style may play a direct role in the regulation of pollen tube growth. The pollen peroxidases may function mainly in growth regulation and tube wall formation and play a role in the interaction between pollen and pistil by metabolizing the phenolic compounds in the pistil.     

Role of quinone reductases in extracellular redox cycling in lichenized ascomycetes

Our previous work showed that many lichenized Ascomycetes can generate hydroxyl radicals using quinone-based extracellular redox cycling. During cycling, hydroquinones must be formed and subsequently regenerated from quinones using a quinone reductase (QR). However, we also showed that no simple correlation exists between QR activity and rates of hydroxyl radical formation. To further investigate the role of QR in hydroxyl radical formation, three model lichen species, Leptogium furfuraceum, Lasallia pustulata and Peltigera membranacea were selected for further investigation. All possessed QR activity and could metabolize quinones, and both Leptogium furfuraceum and Lasallia pustulata actively produced hydroxyl radicals. By contrast, P. membranacea produced almost no hydroxyl radicals, and although the lichen readily metabolized quinones, no hydroquinone production was detected. Peltigera had laccase (LAC) activity that was c. 50 times higher than in the other two species, suggesting that LAC rapidly oxidizes the hydroquinones, preventing radical formation deriving from auto-oxidation. It appears that in some lichens hydroxyl radical formation is blocked by the presence of high redox enzyme activity. QR from P. didactyla was studied further and found to display similar properties to the enzyme from free-living fungi, although it possessed an unusually high molecular mass (c. 62 kDa).     

An evidence of laccases in archaea

Laccases (benzenediol:oxygen oxidoreductase, EC 1.10.3.2) are a diverse group of multicopper oxidases that catalyze the oxidation of a variety of aromatic compounds. Here we present evidence for distribution of laccases among archaea and their probable functions. Putative laccase genes have been found in different archaeal groups that might have branched off early during evolution, e.g. Haloarcula marismortui ATCC 43049, Natronomonas pharaonis DSM2160, Pyrobaculum aerophilum IM2, Candidatus Nitrosopumilus maritimus SCM1, Halorubrum lacusprofundi ATCC 49239. Most of the archaeal multicopper oxidases reported here are of Type 1 and Type 2 whereas type 3 copper-binding domain could be found in Pyrobaculum aerophilum IM2 and Halorubrum lacusprofundi ATCC49239. An analysis of the genome sequence database revealed the presence of novel types of two-domain laccases in archaea. ed using this method. CyMVin the positive samples of Phalaenopsis sp. and Arachnis sp. was confirmed by DNA sequencing and cp gene homeology blast. The results showed that CyMV extracted from the leaves of orchid in Hangzhou, Zhejiang Province, China, could be derived from Kunming city (KM), Yunnan Province, China. This method characterized by high sensitivity, specificity, and precision is suitable for early diagnosis and quantitative detection of CyMV.     

Occurrence of laccases in lichenized ascomycetes of the Peltigerineae

Following our previous findings of high extracellular redox activity in lichens, the results of the work presented here identify the enzymes involved as laccases. Despite numerous data on laccases in fungi and flowering plants, this is the first report of the occurrence of laccases in lichenized ascomycetes. Extracellular laccase activity was measured in 40 species of lichens from different taxonomic groupings and contrasting habitats. Out of 20 species tested from suborder Peltigerineae, 18 displayed laccase activity, while activity was absent in species tested from other lichen groups. Identification of the enzymes as laccases was confirmed by the ability of lichen leachates to readily metabolize substrates such as 2,2′-azino(bis-3-ethylbenzthiazoline-6-sulfonate) (ABTS), syringaldazine and o-tolidine in the absence of hydrogen peroxide, sensitivity of the enzymes to cyanide and azide, the enzymes having typical laccase pH and temperature optima, and an absorption spectrum with a peak at 614 nm. Desiccation and wounding stimulated laccase activity. Laccase activity was not increased after treatment with normal inducers of laccase synthesis, suggesting that they are constitutively expressed. Electrophoresis showed that the active form of laccase from Peltigera malacea was a tetramer with an unusually high molecular mass of 340 kDa and an isoelectric point (pI) of 4.7. The finding of abundant extracellular redox enzymes known to actively produce reactive oxygen species suggest that their roles may include increasing nutrient supply to lichens by delignification, and deterring pathogens by contributing to the oxidative burst. Furthermore, once released into the environment, they may participate in the carbon cycle by facilitating the breakdown or formation of humic substances.     

Kinetic and biochemical properties of high and low redox potential laccases from fungal and plant origin

The electrochemical studies of laccase–mediator systems are aimed at understanding the mechanism of their redox transformation and their efficiency in both homogeneous and heterogeneous reactions; this topic has paramount application spanning from bleaching of paper pulp and the enzymatic degradation of lignin to the biosensors and biofuel cell development. In this paper four different laccases from Trametes hirsuta (ThL), Trametes versicolor (TvL), Melanocarpus albomyces (r-MaL) and Rhus vernicifera (RvL) were characterized from both biochemical and electrochemical points of view. Two of them (TvL and ThL) are high redox potential and two (RvL and r-MaL) are low redox potential laccases. The outline of this work is focused on the determination of catalytic and bioelectrochemical properties of these four enzymes in homogenous solution as well as immobilized onto electrode surface in the presence of a set of different redox mediators. The results measured in the homogenous reaction system correlated well with those measured with the immobilized enzymes. In addition, they are in good agreement with those reported with reference techniques, suggesting that the electrochemical methods employed in this work can be applied well in place of the traditional techniques commonly used for the kinetic characterization of laccases. These results are also discussed in terms of the known amino acid sequences and three-dimensional (3D) structures of the laccases.     

Anti-proliferative lichen compounds with inhibitory activity on 12(S)-HETE production in human platelets

Several lichen compounds, i.e. lobaric acid (1), a β-orcinol depsidone from Stereocaulon alpinum L., (+)-protolichesterinic acid (2), an aliphatic -methylene-γ-lactone from Cetraria islandica Laur. (Parmeliaceae), (+)-usnic acid (3), a dibenzofuran from Cladonia arbuscula (Wallr.) Rabenh. (Cladoniaceae), parietin (4), an anthraquinone from Xanthoria elegans (Link) Th. Fr. (Calaplacaceae) and baeomycesic acid (5), a β-orcinol depside isolated from Thamnolia vermicularis (Sw.) Schaer. var. subuliformis (Ehrh.) Schaer. were tested for inhibitory activity on platelet-type 12(S)-lipoxygenase using a cell-based in vitro system in human platelets. Lobaric acid (1) and (+)-protolichesterinic acid (2) proved to be pronounced inhibitors of platelet-type 12(S)-lipoxygenase, whereas baeomycesic acid (5) showed only weak activity (inhibitory activity at a concentration of 100 μg/ml: 1 93.4±6.62%, 2 98,5±1.19%, 5 14.7±2.76%). Usnic acid (3) and parietin (4) were not active at this concentration. 1 and 2 showed a clear dose–response relationship in the range of 3.33–100 μg/ml. According to the calculated IC₅₀ values the highest inhibitory activity was observed for the depsidone 1 (IC₅₀=28.5 μM) followed by 2 (IC₅₀=77.0 μM). The activity of 1 was comparable to that of the flavone baicalein, which is known as a selective 12(S)-lipoxygenase inhibitor (IC₅₀=24.6 μM).     

Immobilization of wood-rotting fungi laccases on modified cellulose and acrylic carriers

Extracellular laccases produced by three different wood-rotting fungi, Cerrena unicolor, Heterobasidion annosum and Trametes versicolor, were immobilized via covalent bonds formation on DEAE-Granocel 500, CM-Granocel 500, and acrylic carriers. Out of the tested carriers, only the DEAE-Granocel 500, which was activated by divinyl sulphone appeared to be a suitable matrix for the expression of enzymic activity. Only one laccase of all the tested enzymes produced by C. unicolor showed the best binding to the carrier and a satisfactory enzymic activity. The immobilized laccase exhibited the highest enzymic activity at pH 5.2 and it was more resistant to thermal denaturation than the native enzyme. At 90 °C, it retained 75% activity compared to the free enzyme. It was also more stable during storage at 4 °C: after 4 months the immobilized laccase retained 98% of initial activity. Immobilized C. unicolor laccase was active in 10–60% concentration of methanol, acetone, isopropanol or acetonitrile. The best enzymic activity was observed in 20% solution of acetonitrile in buffer.     

Fungal laccases as tools for the synthesis of new hybrid molecules and biomaterials

Laccase is a ligninolytic enzyme widely distributed in wood-rotting fungi and which is also found in a variety of molds and insects as well as some plants and bacteria. Its biological roles range from depolmerization of lignin, coal and humic acids via the oxidation of various mono- and diaromatic structures, to polymerization reactions and pigment formation in microbial cells or spores. Apart from its action in catabolic, depolymerizing and polymerizing processes, laccases have also been shown to be powerful enzymes for coupling two different molecules to create new low-molecular-weight products in high yield. In addition to their homomolecular coupling capabilities, laccases are also able to couple a hydroxylated aromatic substrate with a nonlaccase substrate of variable structure to create new heteromolecular hybrid molecules. Thus, laccases are increasingly finding applications in biotechnology in the fields of environment-friendly synthesis of fine chemicals and for the gentle derivatization of biologically active compounds e.g., antibiotics, amino acids, antioxidants, and cytostatics. Finally, oligomerization and polymerization reactions can lead to new homo- or heteropolymers and biomaterials. These may be useful in a wide range of applications including the production of polymers with antioxidative properties, the copolymerizing of lignin components with low-molecular mass compounds, the coating of cellulosic cotton fibers or wool, the coloring of hair and leathers, or the cross-linking and oligomerization of peptides.     

Production of phenol-oxidizing enzymes in the interaction between white-rot fungi

The role of the phenol-oxidizing enzymes, laccase and peroxidase, was examined in the fungus-to-fungus interaction in dual cultures. Among five white-rot fungi, the following predominance in competition was observed: Pleurotus ostreatus > Trametes versicolor ≧ Pycnoporus coccineus > Ganoderma applanatum > Schizophyllum commune. Both phenol-oxidizing enzyme activities were detected markedly at the confrontation region, and under the mycelia growing over other colonies more than in other areas of the dual culture. This property was most notably observed in the P. ostreatus cultures. The fungi that produce superior active phenol-oxidizing enzymes were predominant in the competition between confronting fungi, indicating that phenol-oxidizing enzymes relate to fungus-to-fungus interaction.     

Hardening by partial dehydration and ABA increase desiccation tolerance in the cyanobacterial lichen Peltigera polydactylon

* BACKGROUND AND AIMS: The ability of partial dehydration and abscisic acid pretreatments to increase desiccation tolerance in the cyanobacterial lichen Peltigera polydactylon was tested. * METHODS: Net photosynthesis and respiration were measured using infrared gas analysis during a drying and rehydration cycle. At the same time, the efficiency of photosystem two was measured using chlorophyll fluorescence, and the concentrations of chlorophyll a were spectrophotometrically assayed. Heat production was also measured during a shorter drying and rehydration cycle using differential dark microcalorimetry. * KEY RESULTS: Pretreating lichens by dehydrating them to a relative water content of approx. 0.65 for 3 d, followed by storing thalli hydrated for 1 d in the light, significantly improved their ability to recover net photosynthesis during rehydration after desiccation for 15 but not 30 d. Abscisic acid pretreatment could substitute for partial dehydration. The improved rates of photosynthesis during the rehydration of pretreated material were not accompanied by preservation of photosystem two activity or chlorophyll a concentrations compared with untreated lichens. Partial dehydration and ABA pretreatments appeared to have little direct effect on the desiccation tolerance of the mycobiont, because the bursts of respiration and heat production that occurred during rehydration were similar in control and pretreated lichens. * CONCLUSIONS: Results indicate that the photobiont of P. polydactylon possesses inducible tolerance mechanisms that reduce desiccation-induced damage to carbon fixation, and will therefore improve the supply of carbohydrates to the whole thallus following stress. In this lichen, ABA is involved in signal transduction pathways that increase tolerance of the photobiont.     

木质素降解酶及相关基因研究进展

生物质的高效综合利用已成为全球关注的热点问题。生物质的主要成分是木质素、纤维素和半纤维素,其利用的关键是如何去除木质素,从而提高纤维素和半纤维素的得率。其中利用真菌的生物预处理方法因条件温和、无二次污染等优点符合全球经济可持续发展需要,受到研究者的普遍关注。综述了近年国内外真菌分泌的主要木质素降解酶,包括木质素过氧化物酶(Li P)、锰过氧化物酶(Mn P)、漆酶(laccase)和多功能过氧化物酶(VP)的主要特点,总结了木质素降解相关酶的基因工程、基因组学的研究成果,并对其发展前景进行了展望。     

Overlap of laccases/cellobiose dehydrogenase activities during the decolourisation of anthraquinonic dyes with close chemical structures by Pycnoporus strains

Pycnoporus strains were used as model to understand the role of laccases in the in vivo decolourisation of three anthraquinonic dyes. The decolourisation capability of Pycnoporus sanguineus MUCL 41582 (PS7), which produces laccases as the main oxidative enzyme, was assayed and compared with the decolourisation capability of a control strain, Pycnoporus cinnabarinus MUCL 39533 (PC330) described as laccase-deficient strain. In absence of dye, laccase activity was observed during the trophophase and the idiophase with PS7, while no laccase activity was observed with PC330. Acid Blue 62 (ABu62), Acid Blue 281 (ABu281) and Reactive Blue 19 (RBu19) caused an increase in laccase activity and surprisingly laccase activity was detected with PC330. In vitro, oxidation of all three anthraquinones by a laccase preparation was obtained to a lesser extent than the whole cell process; suggesting that other factor(s) could be required for a complete decolourisation. As the time space of laccase production in the tested fungi was not perfectly coincidental with the decolourisation process, the activity of cellobiose dehydrogenase (CDH) was monitored. Present early in the broth during the growth of the fungi, CDH displayed in vitro a synergism with laccases in the decolourisation of ABu62, and an antagonism with laccases in the decolourisation of ABu281 and RBu19.