The cell recognition model in chlorolichens involving a fungal lectin binding to an algal ligand can be extended to cyanolichens

Leptogium corniculatum, a cyanolichen containing Nostoc as photobiont, produces and secretes arginase to culture medium containing arginine. This secreted arginase was pre‐purified by affinity chromatography on beads of activated agarose to which a polygalactosylated urease, purified from Evernia prunastri, was attached. Arginase was eluted from the beads with 50 mm α‐d ‐galactose. The eluted arginase binds preferentially to the cell surface of Nostoc isolated from this lichen thallus, although it is also able to bind, to some extent, to the cell surface of the chlorobiont isolated from E. prunastri. Previous studies in chlorolichens have shown that a fungal lectin that develops subsidiary arginase activity can be a factor in recognition of compatible algal cells through binding to a polygalactosylated urease, which acts as a lectin ligand in the algal cell wall. Our experiments demonstrate that this model can now be extended to cyanolichens.     

A cyanobacterial β-actin-like protein,responsible for lichenized <Emphasis Type="Italic">Nostoc</Emphasis> sp. motility towards a fungal lectin

Lichenized Nostoc cells isolated from the lichen Peltigera canina develop chemotactic movement towards a lectin purified from the lichen thallus. Inhibitors of cytoskeleton dynamics, such as phalloidin, latrunculin A and blebbistatin, impede cell displacement. The inhibition of chemotaxis produced by the combined action of phalloidin and blebbistatin is largely reversed by GTP and its analogs, GTP(γ)S and GDP(β)S, as well as by cyclic AMP. Movement implies a rearrangement of the cytoskeleton causing cell polarity, which is, in turn, inhibited by phalloidin and latrunculin A, as revealed by confocal microscopy. F-actin fibers composing Nostoc cytoskeleton have been visualized by immunocytochemical techniques associated with transmission electron microscopy.     

Fungal lectin of Peltigera canina induces chemotropism of compatible Nostoc cells by constriction-relaxation pulses of cyanobiont cytoskeleton

A glycosylated arginase acting as a fungal lectin from Peltigera canina is able to produce recruitment of cyanobiont Nostoc cells and their adhesion to the hyphal surface. This implies that the cyanobiont would develop organelles to motility toward the chemoattractant. However when visualized by transmission electron microscopy, Nostoc cells recently isolated from P. canina thallus do not reveal any motile, superficial organelles, although their surface was covered by small spindles and serrated layer related to gliding. The use of S-(3,4-dichlorobenzyl)isothiourea, blebbistatin, phalloidin and latrunculin A provide circumstantial evidence that actin microfilaments rather than MreB, the actin-like protein from prokaryota, and probably, an ATPase which develops contractile function similar to that of myosin II, are involved in cell motility. These experimental facts, the absence of superficial elements (fimbriae, pili or flagellum) related to cell movement, and the appearance of sunken cells during of after movement verified by scanning electron microscopy, support the hypothesis that the motility of lichen cyanobionts could be achieved by contraction-relaxation episodes of the cytoskeleton induced by fungal lectin act as a chemoattractant.Key words: F-actin, chemotropism, contractile protein, nostoc, Peltigera canina     

Photosynthetic CO2-use efficiency in lichens and their isolated photobionts: the possible role of a CO2-concentrating mechanism

The CO₂ dependence of net CO₂ assimilation was examined in a number of green algal and cyanobacterial lichens with the aim of screening for the algal/cyanobacterial CO₂-concentrating mechanism (CCM) in these symbiotic organisms. For the lichens Peltigera aphthosa (L.) Willd., P. canina (L.) Willd. and P. neopolydactyla (Gyeln.) Gyeln., the photosynthetic performance was also compared between intact thalli and their respective photobionts, the green alga Coccomyxa PA, isolated from Peltigera aphthosa and the cyanobacterium Nostoc PC, isolated from Peltigera canina. More direct evidence for the operation of a CCM was obtained by monitoring the effects of the carbonic-anhydrase inhibitors acetazolamide and ethoxyzolamide on the photosynthetic CO₂use efficiency of the photobionts. The results strongly indicate the operation of a CCM in all cyanobacterial lichens investigated and in cultured cells of Nostoc PC, similar to that described for free-living species of cyanobacteria. The green algal lichens were divided into two groups, one with a low and the other with a higher CO₂-use efficiency, indicative of the absence of a CCM in the former. The absence of a CCM in the low-affinity lichens was related to the photobiont, because free-living cells of Coccomyxa PA also apparently lacked a CCM. As a result of the postulated CCM, cyanobacterial Peltigera lichens have higher rates of net photosynthesis at normal CO₂ compared with Peltigera aphthosa. It is proposed that this increased photosynthetic capacity may result in a higher production potential, provided that photosynthesis is limited by CO₂ under natural conditions.     

A Lichen Lectin Specifically Binds to the α-1,4-Polygalactoside Moiety of Urease Located in the Cell Wall of Homologous Algae

A lectin from the lichen Evernia prunastri developing arginase activity (EC. 3.5.3.1) binds to the homologous algae that contain polygalactosilated urease (EC. 3.5.1.5) in their cell walls acting as a lectin ligand. The enzyme bound to its ligand shows to be inactive to hydrolyze of arginine. Hydrolysis of the galactoside moiety of urease in intact algae with α-1,4-galactosidase (EC. 3.2.1.22) releases high amount of D-galactose and impedes the binding of the lectin to the algal cell wall. However, the use of β-,4-galactosidase (EC.3.2.1.23) releases low amounts of D-galactose from the algal cell wall and does not change the pattern of binding of the lectin to its ligand. The production of glycosilated urease is restricted to the season in which algal cells divide and this assures the recognition of new phycobiont produced after cell division by its fungal partner.Key Words: arginase, cell wall, evernia prunastri, lectin ligand, phycobiont, urease     

Sequence Variation of the tRNALeu Intron as a Marker for Genetic Diversity and Specificity of Symbiotic Cyanobacteria in Some Lichens

We examined the genetic diversity of Nostoc symbionts in some lichens by using the tRNA^Leu (UAA) intron as a genetic marker. The nucleotide sequence was analyzed in the context of the secondary structure of the transcribed intron. Cyanobacterial tRNA^Leu (UAA) introns were specifically amplified from freshly collected lichen samples without previous DNA extraction. The lichen species used in the present study were Nephroma arcticum, Peltigera aphthosa, P. membranacea, and P. canina. Introns with different sizes around 300 bp were consistently obtained. Multiple clones from single PCRs were screened by using their single-stranded conformational polymorphism pattern, and the nucleotide sequence was determined. No evidence for sample heterogenity was found. This implies that the symbiont in situ is not a diverse community of cyanobionts but, rather, one Nostoc strain. Furthermore, each lichen thallus contained only one intron type, indicating that each thallus is colonized only once or that there is a high degree of specificity. The same cyanobacterial intron sequence was also found in samples of one lichen species from different localities. In a phylogenetic analysis, the cyanobacterial lichen sequences grouped together with the sequences from two free-living Nostoc strains. The size differences in the intron were due to insertions and deletions in highly variable regions. The sequence data were used in discussions concerning specificity and biology of the lichen symbiosis. It is concluded that the tRNA^Leu (UAA) intron can be of great value when examining cyanobacterial diversity.     

LEC-2, a highly variable lectin in the lichen Peltigera membranacea

Lectins are a diverse group of carbohydrate binding proteins often involved in cellular interactions. A lectin gene, lec-2, was identified in the mycobiont of the lichen Peltigera membranacea. Sequencing of lec-2 open reading frames from 21 individual samples showed an unexpectedly high level of polymorphism in the deduced protein (LEC-2), which was sorted into nine haplotypes based on amino acid sequence. Calculations showed that the rates of nonsynonymous versus synonymous nucleotide substitutions deviated significantly from the null hypothesis of neutrality, indicating strong positive selection. Molecular modeling revealed that most amino acid replacements were around the putative carbohydrate-binding pocket, indicating changes in ligand binding. Lectins have been thought to be involved in the recognition of photobiont partners in lichen symbioses, and the hypothesis that positive selection of LEC-2 is driven by variation in the Nostoc photobiont partner was tested by comparing mycobiont LEC-2 haplotypes and photobiont genotypes, as represented by the rbcLX region. It was not possible to pair up the two types of marker sequences without conflicts, suggesting that positive selection of LEC-2 was not due to variation in photobiont partners.     

The occurrence of fimbriae on a N 2 2 -fixing cyanobacterium which occurs in lichen symbiosis

The Nostoc cyanobiont of the lichen Peltigera canina when grown on N₂ possesses, in the motile stage, discrete unbranched non-flagellar appendages (fimbriae or pili). These arise from the host cell surface in a peritrichous manner, have an axial hole, are 7.0 ±0.3 nm in diameter and are up to 3 m long. They do not haemagglutinate guinea pig red blood corpuscles and differ from the major fimbrial types reported for Gram-negative heterotrophic bacteria and from sex pili. They may be involved in motility and specificity in symbiotic cyanobacteria.     

DIFFERENCES BETWEEN CULTURED AND FRESHLY ISOLATED CYANOBIONT FROMPELTIGERA—IS THERE SYMBIOSIS-SPECIFIC REGULATION OF A GLUCOSE CARRIER?

The cyanobiont (Nostoc) of the lichenPeltigera horizontaliswas isolated using a procedure of repeated grinding, differential centrifugation and partitioning in an aqueous two-phase system of dextran/polyethylene glycol. A yield of 22% was calculated on the basis of chlorophyll recovery from the thallus. Freshly isolatedNostocdiffered little from that kept in prolonged culture with respect to the relative activities of a number of enzymes of carbohydrate metabolism in the soluble fraction. However, much higher specific activities of the disproportionating transglycosylase and starch phosphorylase, higher intracellular concentrations of glucose, maltooligosaccharides and glycogen and a lower rate of glucose uptake were evident in freshly isolatedNostoc. These activities and pool sizes, as well as CO₂-fixation capability, stayed roughly constant for at least 5 h after isolation; glucose release, which is characteristic for the symbioticNostoc, dropped sharply within 1 h. These observations suggest the transport of glucose out of the cell, rather than that the activities of cytoplasmic enzymes may be a point of early regulation during transition ofNostocfrom the lichenized to the free-living state.     

Evidence for the functioning of photosynthetic CO2-concentrating mechanisms in lichens containing green algal and cyanobacterial photobionts

The photosynthetic properties of a range of lichens containing both green algal (11 species) and cyanobacterial (6 species) photobionts were examined with the aim of determining if there was clear evidence for the operation of a CO₂-concentrating mechanism (CCM) within the photobionts. Using a CO₂-gas-exchange system, which allowed resolution of fast transients, evidence was obtained for the existence of an inorganic carbon pool which accumulated in the light and was released in the dark. The pool was large (500–1000 nmol · mg Chl) in cyanobacterial lichens and about tenfold smaller in green algal lichens. In Hypogymnia physodes (L.) Nyl., which contains the green alga Trebouxia jamesii, a small inorganic carbon pool was rapidly formed in the light. Carbon dioxide was released from this pool into the gas phase upon darkening within about 20 s when photosynthesis was inhibited by the carbon-reduction-cycle inhibitor glycolaldehyde. In the absence of this inhibitor, release appeared to be obscured by carboxylation of ribulose bisphosphate. The kinetics of CO₂ uptake and release were monophasic. The operation of an active CCM could be distinguished from passive accumulation and release accompanying the reversible light-dependent alkalization of the stroma by the presence of saturation characteristics with respect to external CO₂. In Peltigera canina (L.) Willd., which contains the cyanobacterium Nostoc sp., a larger CO₂ pool was taken up over a longer period in the light and the release of this pool in the dark was slow, lasting 3–5 min. This pool also accumulated in the presence of glycolaldehyde, and under these conditions the CO₂ release was biphasic. In both species, photosynthesis at low CO₂ was inhibited by the carbonic-anhydrase inhibitor ethoxyzolamide (EZ). Inhibition could be reversed fully or to a considerable extent by high CO₂. In Peltigera, EZ decreased both the accumulation of the CO₂ pool by the CCM and the rate of photosynthesis. Free-living cultures of Nostoc sp. showed a similar effect of EZ on photosynthesis, although it was more dramatic than that seen with the lichen thalli. In contrast, in Hypogymnia, EZ actually increased the size of the CO₂ pool, although it inhibited photosynthesis. This effect was also seen when glycolaldehyde was present together with EZ. Surprisingly, EZ did not alter the kinetics of either CO₂ uptake or release. Taken together, the evidence indicates the operation in cyanobacterial lichens of a CCM which is capable of considerable elevation of internal CO₂ and is similar to that reported for free-living cyanobacteria. The CCM of green algal lichens accumulates much less CO₂ and is probably less effective than that which operates in cyanobacterial lichens.     

Increased arginase activity during lymphocyte mitogenesis

A sensitive assay for arginase activity was developed using [guanidino-¹⁴C]arginine as substrate and measuring the production of ¹⁴CO₂ from [¹⁴C]urea in the presence of urease. Arginase activity was measured in bovine lymphocytes after activation by Concanavalin A. The specific enzymatic activity of arginase doubled in 6 hours and increased nearly 4-fold by 24 hours after stimulation. It is suggested that the role of arginase in these cells is to provide ornithine as substrate for the synthesis of putrescine, precursor of the polyamines spermidine and spermine.     

Water relation parameters of six Peltigera species correlate with their habitat preferences

Water relation parameters were measured in six congeneric lichen species with different requirements for water availability and with green algae (Peltigera aphthosa, Peltigera leucophlebia, Peltigera venosa) or cyanobacteria (Peltigera horizontalis, Peltigera praetextata, Peltigera rufescens) as main photobionts. Pressure–volume analysis was performed with a dewpoint hygrometer and integrated with anatomical analyses. The Peltigera species typical of arid environments were characterized by relatively lower osmotic potential (π₀) and turgor loss point (Ψ_TLP), and higher values of bulk modulus of elasticity (?). Both π₀ and Ψ_TLP were correlated with the size of medullary cells, while ? was negatively correlated with cell dimensions. The adaptive value of low Ψ_TLP might reside in the capability to maintain cell turgor for longer time intervals under dry conditions. High ? might allow xerophilous lichens to regain cell turgor more promptly even for small amounts of water uptake, thus enlarging the cumulative period of positive carbon balance in environments with fluctuating water availability. The influence of the photobiont type is also discussed.     

Arginase activity in frog urinary bladder epithelial cells and its involvement in regulation of nitric oxide production

The activity of arginase converting arginine into ornithine and urea is of particular interest among many factors regulating NO production in the cells. It is known that by competing with NO-synthase for common substrate (arginine), arginase can affect NO synthesis. In the present work, properties of arginase from the common frog Rana temporaria L. urinary bladder epithelial cells containing the NO-synthase were characterized, and possible contribution of arginase to regulation of NO production by epithelial cells was studied. It has been shown that the enzyme has temperature optimum in the range of 55–60°C, K _M for arginine 23 mM, and V _max about 10 nmole urea/mg of protein/min, and its activity was efficiently inhibited by (S)-(2-boronoethyl)-L-cysteine (BEC), an inhibitor of arginase, at concentrations from 10^?6 to 10^?4 M. The comparison of arginase activity in various frog tissues revealed the following pattern: liver > kidney > brain > urinary bladder (epithelium) > heart > testis. The arginase activity in isolated urinary bladder epithelial cells was 3 times higher that in the intact urinary bladder wall. To evaluate the role of arginase in regulation of NO production, the epithelial cells were cultivated in the media L-15 or 199 containing different amounts of arginine; the concentration of NO₂ ^?, the stable NO metabolites, was de-termined in the cultural fluid after 18–20 h of cell incubation. The vast majority of the produced nitrites are associated with NOS activity, as L-NAME, the NO inhibitor, decreased their accumulation by 77.1% in the L-15 medium and by 80% in the 199 medium. BEC (10^?4 M) increased nitrite production by 18.0% ± 2.7% in the L-15 medium and by 24.4% ± 3.5% in the 199 medium (p < 0.05). The obtained data indicate a relatively high activity of arginase in the frog urinary bladder epithelium and its involvement in regulation of NO production.     

Nitrogenase activity and dark CO2 fixation in the lichen Peltigera aphthosa Willd

The lichen Peltigera aphthosa consists of a fungus and green alga (Coccomyxa) in the main thallus and of a Nostoc located in superficial packets, intermixed with fungus, called cephalodia. Dark nitrogenase activity (acetylene reduction) of lichen discs (of alga, fungus and Nostoc) and of excised cephalodia was sustained at higher rates and for longer than was the dark nitrogenase activity of the isolated Nostoc growing exponentially. Dark nitrogenase activity of the symbiotic Nostoc was supported by the catabolism of polyglucose accumulated in the ligh and which in darkness served to supply ATP and reductant. The decrease in glucose content of the cephalodia paralleled the decline in dark nitrogenase activity in the presence of CO₂; in the absence of CO₂ dark nitrogenase activity declined faster although the rate of glucose loss was similar in the presence and absence of CO₂. Dark CO₂ fixation, which after 30 min in darkness represented 17 and 20% of the light rates of discs and cephalodia, respectively, also facilitated dark nitrogenase activity. The isolated Nostoc, the Coccomyxa and the excised fungus all fixed CO₂ in the dark; in the lichen most dark CO₂ fixation was probably due to the fungus. Kinetic studies using discs or cephalodia showed highest initial incorporation of ¹⁴CO₂ in the dark in to oxaloacetate, aspartate, malate and fumarate; incorporation in to alanine and citrulline was low; incorporation in to sugar phosphates, phosphoglyceric acid and sugar alcohols was not significant. Substantial activities of the enzymes phosphoenolpyruvate (PEP) carboxylase (EC 4.1.1.31) and carbamoyl-phosphate synthase (EC 2.7.2.5 and 2.7.2.9) were detected but the activities of PEP carboxykinase (EC 4.1.1.49) and PEP carboxyphosphotransferase (EC 4.1.1.38) were negligible. In the dark nitrogenase activity by the cephalodia, but not by the free-living Nostoc, declined more rapidly in the absence than in the presence of CO₂ in the gas phase. Exogenous NH ₄ ⁺ inhibited nitrogenase activity by cephalodia in the dark especially in the absence of CO₂ but had no effect in the light. The overall data suggest that in the lichen dark CO₂ fixation by the fungus may provide carbon skeletons which accept NH ₄ ⁺ released by the cyanobacterium and that in the absence of CO₂, NH ₄ ⁺ directly, or indirectly via a mechanism which involves glutamine synthetase, inhibits nitrogenase activity.Abbreviations CP carbamoyl phosphate - EDTA ethylenedi-amine tetraacetic acid - PEP phosphoenolpyruvate - RuBP ribulose 1,5 bisphosphate     

STUDIES WITH CYANIDIUM CALDARIUM : I. The Fine Structure and Systematic Position of the Organism

The fine structure of Cyanidium caldarium, as seen in thin sections of KMnO₄-fixed cells examined with the electron microscope, is described. This organism, whose taxonomic position among algae is undetermined, contains a single well defined chloroplast, a nucleus, and mitochondria. Studies, with the electron microscope, of Chlorella pyrenoidosa and Nostoc are also reported. Structural differences within cells of Cyanidium, chlorella, and Nostoc are discussed. It is concluded that if Nostoc can be taken as a typical Cyanophyte and Chlorella as a representative Chlorophyte and if the items of fine structure examined are diagnostic, then Cyanidium is certainly not a Cyanophyte and, while it has numerous features in common with Chlorella, is not a green alga similar to Chlorella. Comparisons are also made between Cyanidium and other algae whose fine structure has been described by others.     

PRELIMINARY OBSERVATIONS ON THE GROWTH OF TRANSPLANTEDPELTIGERA CANINAUNDER SEMI-NATURAL CONDITIONS

Peltigera caninathalli have been successfully transplanted onto soil in a garden and in flowerpots. Garden samples showed marked seasonality and achieved growth rates of 6·4 cm per year. Pot-grown samples showed variation in the growth of individual thallus lobes and established that, under different soil hydration regimes, permanently hydrated thalli could sustain considerable linear growth rates for at least 140 days.     

Identification and Characterization of Proteins Involved in Rice Urea and Arginine Catabolism

Rice (Oryza sativa) production relies strongly on nitrogen (N) fertilization with urea, but the proteins involved in rice urea metabolism have not yet been characterized. Coding sequences for rice arginase, urease, and the urease accessory proteins D (UreD), F (UreF), and G (UreG) involved in urease activation were identified and cloned. The functionality of urease and the urease accessory proteins was demonstrated by complementing corresponding Arabidopsis (Arabidopsis thaliana) mutants and by multiple transient coexpression of the rice proteins in Nicotiana benthamiana. Secondary structure models of rice (plant) UreD and UreF proteins revealed a possible functional conservation to bacterial orthologs, especially for UreF. Using amino-terminally StrepII-tagged urease accessory proteins, an interaction between rice UreD and urease could be shown. Prokaryotic and eukaryotic urease activation complexes seem conserved despite limited protein sequence conservation for UreF and UreD. In plant metabolism, urea is generated by the arginase reaction. Rice arginase was transiently expressed as a carboxyl-terminally StrepII-tagged fusion protein in N. benthamiana, purified, and biochemically characterized (K_m = 67 mm, k_cat = 490 s⁻¹). The activity depended on the presence of manganese (K_d = 1.3 μm). In physiological experiments, urease and arginase activities were not influenced by the external N source, but sole urea nutrition imbalanced the plant amino acid profile, leading to the accumulation of asparagine and glutamine in the roots. Our data indicate that reduced plant performance with urea as N source is not a direct result of insufficient urea metabolism but may in part be caused by an imbalance of N distribution.Nitrogen (N) availability often limits plant performance in natural ecosystems (Vitousek and Howarth, 1991), causing a selective pressure to optimize the use of N resources. This ecophysiological selection has even led to a reduction of the N content of plant proteins in comparison with animal orthologs (Elser et al., 2006). Because N is a limiting resource, plants do not only require efficient N uptake mechanisms but also possess enzymatic pathways for N remobilization.Arg is the most important single metabolite for N storage in plant seeds. In a survey of 379 plant species, Arg N accounted on average for 17.3% of total seed N (Vanetten et al., 1967). In several rice (Oryza sativa) varieties, values ranging from 16.1% to 17.1% were measured (Mosse et al., 1988). To access the N stored in the guanidinium group of Arg, it must first be hydrolyzed by mitochondrial arginase to Orn and urea. Urea leaves the mitochondria and is hydrolyzed by urease in the cytosol, releasing ammonia, which is reassimilated into amino acids by the combined action of Gln synthetase and Glu synthase.Urea not only originates from Arg breakdown but may also be taken up from the environment by urea transporters (Kojima et al., 2007; Wang et al., 2008). Therefore, urease is involved in N remobilization as well as in primary N assimilation. Plant ureases and arginases are housekeeping enzymes found in many if not all plant species (Witte and Medina-Escobar, 2001; Brownfield et al., 2008). Urease is a nickel metalloenzyme that in Arabidopsis (Arabidopsis thaliana) requires three urease accessory proteins (UAPs; AtUreD, AtUreF, and AtUreG) for activation (Witte et al., 2005a). Studies in bacteria demonstrated that UAPs form a complex with apo-urease and are required for posttranslational Lys carboxylation of apo-urease and the subsequent incorporation of two nickel ions into the active center. After activation, the UAPs dissociate from urease. The exact molecular function of each accessory protein in this process is not yet understood (Carter et al., 2009). Like urease, arginase is a metalloenzyme. It is best activated by manganese (Carvajal et al., 1996; Hwang et al., 2001), not requiring accessory proteins for activation.Urea plays an important role in agriculture because it is the most used N fertilizer worldwide (http://www.fertilizer.org/ifa), intensively employed in Asia for the cultivation of rice. Urea N partly reaches the plant as ammonium or nitrate because the fertilizer is already degraded in the environment by microbial ureases and may then be subject to nitrification. Alternatively, plants are capable of taking up urea from fertilization directly and assimilate its N (Kojima et al., 2007; Wang et al., 2008). Although rice is a major crop plant and rice production is heavily dependent on urea fertilization, the enzymes and the corresponding genes involved in rice urea metabolism have not yet been investigated. In this study, we identified the genes and cloned the corresponding cDNAs coding for rice arginase, urease, and the UAPs UreD, UreF, and UreG. The functionality of the corresponding proteins was demonstrated and biochemical parameters were determined. The general gene and protein structure of plant UreD and UreF were investigated and a direct interaction of rice UreD with apo-urease was discovered, leading to a refinement of the mechanistic view of plant urease activation. In physiological experiments, rice urease and arginase activities showed no significant response to different N-fertilizing regimes, while the amino acid composition in urea-grown plants was strongly imbalanced, indicating that urea N disturbs plant metabolism downstream of N assimilation.     

Preservation of secondary fungal metabolites in herbarium lichen specimens

Fresh picked and herbarium thalli of Cladonia stellaris, C. rangiferina, Allocetraria nivalis, A. cucullata, Cetraria islandica, Peltigera canina, and Nephroma articum epigene lichens were studied using the immune-enzyme analysis. No big difference was observed in the contents of mycotoxin secondary metabolites, i.e., deoxynivalenol, diacetoxyscirpenol, zearalenone, alternariol, citrinin, sterigmatocystin, cyclopiazonic acid, mycophenolic acid, emodin, and PR-toxin. The discovery of these substances in the specimens preserved for several decades shows that lichens have an effective system of conservation of metabolic exchange products.     

Expression, purification, and biochemical properties of arginase from Bacillus subtilis 168

The arginine-degrading and ornithine-producing enzymes arginase has been used to treat arginine-dependent cancers. This study was carried out to obtain the microbial arginase from Bacillus subtilis, one of major microorganisms found in fermented foods such as Cheonggukjang. The gene encoding arginase was isolated from B. subtilis 168 and cloned into E. coli expression plasmid pET32a. The enzyme activity was detected in the supernatant of the transformed and IPTG induced cell-extract. Arginase was purified for homogeneity from the supernatant by affinity chromatography. The specific activity of the purified arginase was 150 U/mg protein. SDS-PAGE analysis revealed the molecular size to be 49 kDa (Trix·Tag, 6×His·Tag added size). The optimum pH and temperature of the purified enzyme with arginine as the substrate were pH 8.4 and 45°C, respectively. The K_m and V_max values of arginine for the enzyme were 4.6 mM and 133.0 mM/min/mg protein respectively. These findings can contribute in the development of functional fermented foods such as Cheonggukjang with an enhanced level of ornithine and pharmaceutical products by providing the key enzyme in arginine-degradation and ornithine-production.