Effect of Spruce Root Constituents on Extracellular Enzymes of Fomes annosus

Fractions of acetone extracts from heartwood, sapwood and wood from the reaction zone in roots of Norway spruce, attacked by Fomes annosus, were tested concerning their effect on the activity of cellulase, polygalacturonase, aryl-β-glucosidase and laccase, obtained from culture filtrates of the same fungus. A specific inhibition of polygalacturonase was recorded with the resinous fractions. The hydrolysing enzymes were more inhibited by the lignans of the reaction zone in the presence of fungal laccase than in the absence of laccase. The pH dependence of the inhibiting effect of phenols varied among the enzymes. The four enzymes were inhibited by partly different lignan fractions, and synergistic effects between minor compounds were indicated. The phenolic fractions inhibited weakly the biosynthesis of the enzymes. It was obvious that results from enzyme inhibition studies in vitro do not reflect the complicated mutual interrelationships between production and activity of the extracellular fungal enzymes and the chemical constituents of the host in vivo.     

Changes in Sapwood of Roots of Norway Spruce, Attacked by Fomes annosus. Part I

Chemical and physiological changes occurring in root sapwood of Norway spruce (Picea abies [L.] Karst.), when attacked by Fomes annosus (Fr.) Cke, were studied. The transformation of sapwood to reaction zone, induced by the fungal attack, implies a very sharp increase of carbonate content, correlated with higher amounts of potassium, calcium and magnesium. The buffer capacity of the reaction zone is strong, especially in the pH range 6–9. The high peroxidase activity in the rays of the sapwood is almost totally absent in the reaction zone, probably due to inactivating phenolic compounds. o-Diphenol oxidase was detectable only in the presence of microorganisms. p-Diphenol oxidase was active in connection with decaying wood but not in the reaction zone.     

Aporphine alkaloids and lignans formed in response to injury of sapwood in Liriodendron tulipifera

Two new phenolic aporphine alkaloids, (+)-lirioferine and (+)liriotulipiferine, were isolated from discolored sapwood of L. tulipifera. Injury to the tree stem greatly stimulated biosynthesis of glaucine and phenolic alkaloids related to glaucine including thaliporphine, predicentrine, N-methylaurotetanine and corunine as well as the above two compounds. Injury also stimulated synthesis of oxoaporphine related and other polymeric pigments. Corunine was responsible for at least part of the color of discolored sapwood. None of the above compounds except glaucine was detected in normal sapwood or heartwood of L. tulipifera. Thus, formation of alkaloids and lignans in discolored sapwood differs both quantitatively and qualitatively from that observed during the normal transition of sapwood to heartwood in this tree. The compounds formed in response to injury differed substantially from one zone of injury to another within the same tree.     

SPHEROSOMES AND MITOCHONDRIA IN THE LIVING FUNGAL CELL

Study of living hyphae of Fusarium oxysporum Schlect., Fomes annosus (Fries) Cooke, Ceratocystis fagacearum (Bretz) Hunt, Basidiobolus ranarum Eidam, and Mycotypha microspora Fenner with phase contrast revealed that these fungi have spherosomes similar to those in vascular plants. The spherosomes are conspicuous in the hyphal tip, suggesting some function other than fat synthesis. It may be that the Woronin bodies reported by other workers are spherosomes. Mitochondria in these fungi are highly pleomorphic and exhibit saltatory movement. They often interact with nuclei in a manner suggesting close membrane contact.     

In vitro inhibition of root-rot pathogensPhellinus weirii,Armillariella mellea,Fomes annosus,andPhytophthora cinnamomi by a newly isolatedBacillus sp.

A Gram-positive bacterium that inhibits several root-rot pathogens was isolated from alder forest soil on the Oregon coast. This organism, similar toBacillus cereus, produces in culture media a heat-stable, broad-spectrum antibiotic which inhibits growth of four important Northwest conifer root disease fungi:Phellinus weirii (Murr.) Gilbertson,Fomes annosus (Fr.) Cke.,Armillariella mellea (Fr.) Karst., andPhytophthora cinnamomi Rands.     

Resin and the Resistance of Conifers to Fomes annosus

Roots of young trees of different conifer species, Scots pine,Corsican pine, Sitka spruce, and Douglas fir were inoculatedwith Fomes annosus. In the pines, infection was negligible butin the other genera the central wood was extensively invaded.The process of infection was studied further in Sitka spruceby means of a root-severing technique in which an inoculum blockwas forced between the cut ends of a root. In most trees a centralrot developed which in some extended up into the butt: the meanextent of growth recorded was 30 cm in 14 months. In the severedroot portions infection also occurred but F. annosus was subsequentlyreplaced to a considerable extent by other micro-organisms,particularly in trees growing on a peat soil. A similar centralrot developed after inoculations of Norway spruce. The resistance of pine sapwood and the outer wood of spruceand Douglas fir can be explained at least partially by the structureand viability of the resin duct system. Larch, Douglas fir,spruce, and pine form a series showing increasing complexityand activity of the resin system. In addition, studies carriedout on the resin yields of pines growing under different conditionsshowed that the resistance of a tree to F. annosus is correlatedwith its ability to mobilize resin. Site factors, forest management,host age vigour, genetic constitution, and past history mayall influence resin mobilization.     

Lipids and sterols of Pinus sylvestris L. sapwood and heartwood

Summary The lipid and sterol content and composition of three lipid fractions (free fatty acids/ sterols, triacylglycerols and sterol/triterpenoid esters) extracted from three stem discs of Pinus sylvestris were assessed to investigate metabolic changes related to heartwood formation. The wood was separated into (1) cambial zone, (2) outer sapwood, (3) inner sapwood, (4) transition zone, (5) outer heartwood and 6) inner heart-wood. The fractions were separated by thin-layer chromatography (TLC) and analysed by gas-liquid chromatography (GLC). The amount of fatty acids of sapwood triacylglycerols was about 1.5% (dry wt.) but a large reduction occurred in the transition zone. In contrast, noticeable amounts of free fatty acids were present only in the heart-wood. The most important fatty acids in the sapwood fractions were 16:0, 18:0, 18:1, 18:2 (the dominant fatty acid in all fractions), 18:3 and 20:3. Together 18:1 and 18:2 formed about 70% of the total triacylglycerol fatty acids. Of the sterol/ triterpenoid esters, 18:2 and 18:3 were predominant. The fatty acid composition of all fractions changed in the transition zone. The sterols found were sitosterol, stigmastanol, campesterol and campestanol. The amount of sterol esters increased towards the heartwood, and the amount of free sterols was lowest in the inner sapwood. Sitosterol was the dominant sterol in both free sterols and sterol esters.     

NUCLEAR BEHAVIOR IN THE BASIDIUM OF FOMES ANNOSUS

Meiotic division in Fomes annosus is similar to that reported for other higher fungi. Nuclei in dikaryotic cells prior to fusion in the basidia are long, thin, and double-stranded with paired heterochromatic areas. Various stages of prophase are similar to those in higher plants. At metaphase I and II seven pairs of chromosomes are aligned in a circle and the chromatids migrate to opposite poles established by two centrioles. The centrioles function in the movement of the nuclei in the basidium, nuclear alignment prior to fusion, establishment of poles for division, and the migration of the nuclei into the basidiospore. After nuclei migrate into the basidiospore, they soon divide, producing a binucleate spore.     

Function of laccase in the white-rot fungus Fomes annosus

1. Thioglycolic acid, a Cu-chelating agent, totally inhibited extracellular laccase activity without affecting growth and morphology of Fomes annosus.
2. In the presence of thioglycolic acid Fomes annosus cleaved high molecular weight lignosulfonate with a molecular weight range of 2×10⁶ to 1000. In the absence of thioglycolic acid the polymerizing activity of laccase prevented the detection of lignosulfonate breakdown products.
3. Oxidative polymerization of a lignin monomer, coniferyl alcohol, occurred in the presence but not in the absence of laccase activity.
4. Catechol and guaiacol added to the medium at a concentration of 2 mmol, are normally oxidized by fungal laccase and strongly inhibit growth. Presence of thioglycolic acid prevented the oxidation of these phenols and simultaneously permitted normal growth.

     

Antagonism against fomes annosus. Comparison between different test methods in vitro and in vivo

The antagonism of Trichoderma harzianum, Scytalidium album and an unidentified fungus (isolated from Monotropa hypopitys) against the root rot fungus Fomes annosus was studied in vitro and in vivo. Antibiosis was demonstrated on malt extract agar and on powdered wood. Competition between F. annosus and its antagonists was studied in stem discs and in living stems of Norway spruce. Effective antibiotics on agar and sawdust did not always bring about effective antagonism against F. annosus in stem discs or living trees. Factors such as growth rate of the antagonists in wood and their ability to invade the substrate during competition may influence the effectiveness of F. annosus suppression. The results from studies on antagonism in stem discs agreed with the results from tests in living trees. The frequency of penetrations through the wood cell walls was drastically lowered by the presence of the antagonists but was not closely correlated with the abundance of F. annosus.     

The Infection of Pine stumps by Fomes annosus and other fungi

A study of the infection biology of stump-colonizing fungi hasshown that certain species, for instance Fomes annosus, Peniophoragigantea, Stereum sanguinolentum, and several causing blue-stain,initiate infection of fresh stumps by means of air-borne sporeswhich colonize the cut surface. The incidence of natural infectionis reduced considerably by applying creosote to the surfaceimmediately after felling. High resin content of stumps is correlatedwith increased resistance to infection. Marked seasonal variationin the incidence of stump infection by F. annosus and P. giganteawas observed. The spore content of the air, and competitionbetween fungi in stumps, are considered to be important factorsaffecting this variation. Initial colonization of stump roots usually proceeds from thebody of the stump. Invasion of roots by saprophytes presentin the soil or litter also occurs but only many months afterfelling. Crowns of plantation pines may bear many spores of stump-colonizingfungi, including F. annosus. Under the conditions described,the proportion of stump infections ascribable to rain-splash-bornespores was small compared with that caused by wind-borne spores.     

Further Observations on Fungi Inhabiting Pine Stumps

Growth-rates, both on malt agar and in stump wood, of earlystump colonizers such as Fomes annosus, Pemophora gigantea,Stereum sanguinolentum, and Leptographium lundbergii are higherthan those of later-colonizing agarics. The initial invasionof stump roots usually proceeds via the stump body by fungiwhich infect the cut surface. Although stumps may dry out appreciably shortly after felling,in later stages of decay the moisture content of the wood oftenincreases considerably. Stump decomposition is associated witha succession of decay fungi, the ‘Peniophora’, ‘Hypholoma’,and ‘Tricholoma’ stages being distinguished. Severalphycomycetes and fungi imperfecti colonize decayed, but notfresh, stump wood. P. gigantea is shown to be a vigorous competitor of F. annosusfor initial colonization of stumps: it may also replace F.annosus in stumps. Gliocladium viride and Trichoderma viridecompete with wood-rotting basidiomycetes and sometimes replacethem in very decayed wood.     

Some chemicals to prevent stump colonization by Fomes annosus (Fr.) Cooke

In tests to find a replacement for creosote, widely used for painting conifer stumps to prevent colonization by Fomes annosus, the best all-round results were given by sodium nitrite. This has therefore been introduced in the forest, though, as it is poisonous to man and to animals, urea or disodium octoborate (‘Polybor’) may be used instead where labour cannot be well controlled, or there appears to be a danger to unattended livestock or to water supples.     

6-Methyldehydro-α-lapachone from Fomes annosus

The fructification of Fomes annosus contains 6-methyldehydro-α-lapachone, the characterization of which relies on ¹³C NMR and on synthesis. The synthesis of 7-methyldehydro- α-lapachone is also described.     

Spatial Patterns in Hyphal Growth and Substrate Exploitation within Norway Spruce Stems Colonized by the Pathogenic White-Rot Fungus Heterobasidion parviporum

In Norway spruce, a fungistatic reaction zone with a high pH and enrichment of phenolics is formed in the sapwood facing heartwood colonized by the white-rot fungus Heterobasidion parviporum. Fungal penetration of the reaction zone eventually results in expansion of this xylem defense. To obtain information about mechanisms operating upon heartwood and reaction zone colonization by the pathogen, hyphal growth and wood degradation were investigated using real-time PCR, microscopy, and comparative wood density analysis of naturally colonized trees with extensive stem decay. The hyphae associated with delignified wood at stump level were devoid of any extracellular matrix, whereas incipient decay at the top of decay columns was characterized by a carbohydrate-rich hyphal sheath attaching hyphae to tracheid walls. The amount of pathogen DNA peaked in aniline wood, a narrow darkened tissue at the colony border apparently representing a compromised region of the reaction zone. Vigorous production of pathogen conidiophores occurred in this region. Colonization of aniline wood was characterized by hyphal growth within polyphenolic lumen deposits in tracheids and rays, and the hyphae were fully encased in a carbohydrate-rich extracellular matrix. Together, these data indicate that the interaction of the fungus with the reaction zone involves a local concentration of fungal biomass that forms an efficient translocation channel for nutrients. Finally, the enhanced production of the hyphal sheath may be instrumental in lateral expansion of the decay column beyond the reaction zone boundary.To grow to great heights, trees continually replace their water- and nutrient-conducting elements. Older elements, such as the heartwood that is formed in many trees, gradually become nonconductive. In contrast to the living sapwood, heartwood lacks active defense mechanisms against microbes. However, lignin, the polymer coating cell wall polysaccharides, is highly resistant to microbial degradation. In fact, white-rot fungi, besides having evolved the ability to tolerate or detoxify the secondary metabolites accumulating in heartwood, are the only organisms capable of efficiently degrading lignin. Following establishment in the heartwood of living trees, the colonies of pathogenic white-rot fungi expand and eventually also threaten the conductive sapwood.The white-rot fungus Heterobasidion annosum sensu lato, composed of three species with overlapping geographic distributions and host ranges in Europe (23), is the most important pathogen of Norway spruce (Picea abies L. Karst) in boreal forests. Primary infection of Norway spruce stands by H. annosum sensu lato takes place through fresh thinning stumps or wounds on roots and at the base of the stem. Basidiospores landing on these entrance points give rise to mycelia which colonize the root systems, and eventually the fungus spreads into the stem heartwood. At sites infested with Heterobasidion parviporum, a species primarily restricted to Norway spruce, roots of saplings can become infected by the fungus after around 10 years of growth (25). Stem colonization usually initiates only after the heartwood has started to develop, which in Norway spruce takes place in trees 25 to 40 years old (17). Due to relatively rapid axial spread within heartwood, the decay column caused by H. annosum sensu lato often is up to 10 m high in the stems of mature Norway spruce trees.In response to sapwood challenge by an expanding heartwood-based colony of H. annosum sensu lato, Norway spruce forms a so-called reaction zone (RZ) in the border area between healthy sapwood and colonized heartwood. This xylem defense is characterized by high pH due to increased carbonate content and enrichment of phenolic compounds, particularly lignans, some of which have shown antifungal properties in bioassays (14, 30, 31). Although several wood decay fungi are able to eventually penetrate the RZ regions formed in trees, the strategies employed by fungi to breach these unique defense barriers are poorly understood (24). The purpose of this study was to obtain information about the mechanisms operating in heartwood colonization and expansion of the decay column via penetration of the RZ. To do this, we examined spatial growth of H. parviporum and the associated substrate exploitation patterns within naturally colonized mature stems of Norway spruce.     

Redox‐Active Phenolic Compounds Mediate the Cytotoxic and Antioxidant Effects of Carpodesmia tamariscifolia (=Cystoseira tamariscifolia)

Carpodesmia tamariscifolia is a brown alga rich in (poly)phenols with important cytotoxic and antioxidant effects. However, the relationship between its chemical composition and its effects is unknown. The aim of this study is to identify the potential compounds and mechanisms responsible for its main effects. The alga was extracted consecutively with hexane, dichloromethane and methanol and further fractionated using Sephadex LH‐20 and silica gel columns when appropriate. The fractions were subjected to thin‐layer chromatography and liquid chromatography‐mass spectrometry analysis and evaluated for their total phenolic content (Folin‐Ciocalteu assay), radical scavenging activity (DPPH assay), cytotoxic activity (MTT assay on the SH‐SY5Y cell line), and ability to generate H₂O₂ (Amplex Red assay). Chromatographic and phenolic analyses of the fractions indicate that abundant redox‐active phenols are present in all the fractions and that a high amount of prenylated hydroquinone derivatives is present in the apolar ones. In the hexane and dichloromethane fractions, the cytotoxic and antioxidant activities are closely related to their phenolic content, whereas in the methanol fractions, the cytotoxicity is negatively related to the phenolic content and the antioxidant activity is positively related to it. In the same tests, hydroquinone behaves as both strong cytotoxic and antioxidant agent. H₂O₂ assay shows that C. tamariscifolia fractions and hydroquinone can autoxidize and generate H₂O₂. Our results suggest that redox‐active phenols produce the pharmacological effects described for C. tamariscifolia and that the hydroquinone moiety of prenylated hydroquinone derivatives is responsible for both cytotoxic (through a pro‐oxidant mechanism secondary to its autoxidation) and antioxidant effects of the apolar fractions.     

Influence of Growth Conditions, Metabolic Inhibitors, and Phenolic Compounds on the ATP Pool in Fomes annosus

The ATP pool of growing fungal mycelia, particularly Fomes annosus, has been determined. The ATP level varied during the different growth phases and correlated with the variations in the economic coefficient. Common uncouplers (at concentrations similar to those used in mitochondrial tests) decreased the ATP pool very rapidly. The size of the pool often fell 50–80% before the O₂ uptake decreased below that of the control and was accompanied by an increasing exudation of inorganic phosphate. Phenolic compounds added to the medium stimulated the lacease activity, generally in combination with a decrease in the ATP level.     

Observations on the Biology of Fomes annosus, with Particular Reference to East Anglian Pine Plantations: II. Spore Production, Stump Infection, and Saprophytic Activity in Stumps

F. annosus produces conidia abundantly in culture but rarelyunder natural conditions. Sporophorea are formed on stumps anddying trees throughout the year provided that the humidity issufficiently high. Spore discharge in the plantations may occurat any time of year, but slowa down or ceases during very dryweather. It takes place at low temperatures, ceasing only whensporophores freeze. In the laboratory, F. annosus basidiospores germinate in relativehumidity exceeding 92 per cent. on freshly cut, unsterilizedpine wood. Viability is lost rapidly in light at temperaturesabove 15°C. Under humid conditions F. annosus spores will infect freshlycut pine stumps. There is evidence that spores of F. annosus washed down intosoil remain viable for at least a short period and that stumpscovered with soil are infected from this source. F. annosusspores can infect stumps for only a few weeks after felling,colonization after a longer interval probably beingprevdntedby competing fungi. In stumps inoculated with a mixed suspensionof F. annosus and Peniophora gigantea spores, Fomes at firstcolonized the wood but was soon replaced by P. gigantea. Otheraspects of competition are discussed. The incidence of natural infection in stumps and the factorsaffecting it are discussed Growth rates of F. annosus on malt agar and in lengths of pineroot are given. The fungus grows in stump roots at about 1 m.per year, and so closely approaches adjacent trees within ayear of thinning the plantation: In large stumps, F. annosusmay survive 15 or even 30 years after felling. Data are givenwhich suggest that the infective capacity of stumps containingF. annosus is greater in alkaline than in acid mils, while replacementby other fungi is slower. Competition of F. annosus with other fungi during colonizationof stumps is discussed. The parasite can grow along roots alreadyoccupied by certain fungi but not along roots containing others.The probable course of succession in stumps rotted by F. annousis described.     

Anthraquinones from Trichoderma polysporum

The antagonistic compounds produced by Trichoderma polysporum when in contact with the basidiomycete fungus Fomes annosus were identified as the known anthraquinones pachybasin (2), chrysophanol (3) and emodin (4). Bioassays showed a marked inhibition of F. annosus by the O-acetyl derivatives of 2, 3 and 4.     

Chemical constituents of plants from the genus Symplocos

The chemical constituents of Symplocos genus were reviewed with 90 structures and 28 references cited. These constituents include triterpenoids, flavonoids, lignans, phenols, steroids, alkaloids, and iridoids. Triterpenoids are the dominant constituents within the genus Symplocos, some of them exhibited antiproliferative effects. Some phenolic glycoside derivatives showed inhibitory activity against snake-venom phosphodiesterase I and human nucleotide pyrophosphatase phosphodiesterase.