Evolutionary history of the conifer root rot fungus Heterobasidion annosum sensu lato

We investigated two hypotheses for the origin of the root rot fungus Heterobasidion annosum species complex: (i) that geology has been an important factor for the speciation (ii) that co-evolutionary processes with the hosts drove the divergence of the pathogen species. The H. annosum species complex consists of five species: three occur in Europe, H. annosum s.s., Heterobasidion parviporum and Heterobasidion abietinum, and two in North America, Heterobasidion irregulare and Heterobasidion occidentale; all with different but partially overlapping host preferences. The evolution of the H. annosum species complex was studied using six partially sequenced genes, between 10 and 30 individuals of each species were analysed. Neighbour-joining trees were constructed for each gene, and a Bayesian tree was built for the combined data set. In addition, haplotype networks were constructed to illustrate the species relationships. For three of the genes, H. parviporum and H. abietinum share haplotypes supporting recent divergence and/or possible gene flow. We propose that the H. annosum species complex originated in Laurasia and that the H. annosum s.s./H. irregulare and H. parviporum/H. abietinum/H. occidentale ancestral species emerged between 45 and 60 Ma in the Palaearctic, well after the radiation of the host genera. Our data imply that H. irregulare and H. occidentale were colonizing North America via different routes. In conclusion, plate tectonics are likely to have been the main factor influencing Heterobasidion speciation and biogeography.     

单孢融合性实验法鉴定采自四川北部的小孔异担子菌(英文)

在四川北部九寨沟和黄龙保护区的云杉、松树和铁杉上发现异担子菌 ,并从 6号标本中分离到 73个单孢菌株。在每个标本中随机选取 2个菌株分别与欧洲的原始多年异担子菌、小孔异担子菌和冷杉异担子菌的单孢菌株进行融合性交配。试验表明 ,这 6号标本都是小孔异担子菌。四川的菌株与欧洲的原始多年异担子菌交配不融合 ,而与欧洲的小孔异担子菌完全融合 ,并在交配后的菌落中形成锁状联合 ,且在交配的菌落中不产生拮抗线。虽然四川的菌株与欧洲的冷杉异担子菌有较高的融合性 ,但这些交配大部分为单项交配 ,即只在四川一侧的菌落中产生锁状联合 ,而且在交配的菌落中多数产生拮抗线。研究样品全部采自天然林 ,小孔异担子菌在四川经营林分中的致病性还有待进一步调查。     

Iron and reactive oxygen responses in Pinus sylvestris root cortical cells infected with different species of Heterobasidion annosum sensu lato

Defence mechanisms in trees are not well understood. We assessed whether distribution of iron ions and their co-localisation with reactive oxygen species in Pinus sylvestris root cells reflect differential preferences of the pathogens Heterobasidion annosum sensu stricto, H. parviporum and H. abietinum to the host. Strains of H. annosum s.s. characterised by a greater preference for P. sylvestris induced accumulation of superoxide (O(2) (-)) in host cells 6?h after inoculation, whereas two peaks in accumulation of O(2) (-) (after 4 and 48?h) were observed after infection with strains of the pathogens H. parviporum and H. abietinum, which have a lower preference for P. sylvestris. Moreover, strains of H. annosum s.s. caused increased production of hydrogen peroxide (H(2)O(2)) in P. sylvestris cells, in contrast with strains of the other two species (H. parviporum and H. abietinum). Following inoculation with H. annosum s.s. strains, H(2)O(2) was correlated negatively with O(2) (-) and correlated positively with ferrous iron (Fe(2+)). Co-localisation of Fe(3+) with H(2)O(2) may suggest that they are involved in inducing hypersensitive responses and eventually cell death in roots inoculated with H. annosum s.s. strains, in contrast with H. parviporum, in which other mechanisms operate when the host is parasitised.     

A peroxidase gene family and gene trees in Heterobasidion and related genera

Four putative peroxidase-encoding gene fragments, named mnp1a, mnp1b, mnp2 and mnp3, were amplified with degenerative primers from the white-rot basidiomycete genus Heterobasidion. The fragments were cloned and sequenced. Similar fragments were produced and analyzed from the related genera Amylostereum, Bondarzewia and Echinodontium. Each amplified fragment contains three identically positioned introns. According to the predicted amino acid sequence, these fragments are most similar to two Mn peroxidase-encoding genes (MPGI and mnp2) and gene pgv of Trametes versicolor. Conserved residues thought to be essential for peroxidase function were identified. All four MnP gene loci of Heterobasidion were detected only in H. parviporum. Variation occurred in the predicted amino-acid sequences (131-132 amino acids) of all four fragments originating from the 47 Heterobasidion isolates tested. Amino acid variation in fragments of mnp2 and mnp3 separated European Heterobasidion parviporum ("S-type") and H. abietinum ("F-type"), known to have identical rDNA sequences. Asian and western North American isolates from fir, spruce and other hosts had the peroxidase amino acid sequences of European H. parviporum. American and European H. annosum ("P-type") isolates had different amino acid sequences and might be cryptic species.     

Spread of Heterobasidion annosum s.s. and Heterobasidion parviporum in Picea abies 15 years after stump inoculation

The tree pathogenic fungi Heterobasidion annosum s.s. and Heterobasidion parviporum cause root and butt rot in Norway spruce (Picea abies) and produce serious economic losses to the forest sector in Europe. We experimentally studied inter- and intraspecific differences between H. parviporum and H. annosum s.s. in the way they infect stumps and spread into neighbouring trees. Eleven H. parviporum and nine H. annosum s.s. isolates were artificially inoculated on stumps of two spruce stands after first thinning. After 15 years, the same isolates were reisolated from neighbouring trees. Heterobasidion parviporum spread more frequently from the inoculated stumps to the neighbouring trees than H. annosum s.s. The surroundings of H. annosum s.s. stumps that did not spread were often colonized by H. parviporum. Heterobasidion annosum s.s. spread was restricted mainly to the areas of the plot where no other Heterobasidion genotypes had been inoculated. In such cases, H. annosum s.s. tended to develop into bigger genets than H. parviporum. The probability of stump-to-tree spread of H. parviporum depended on the diameter of the stumps, suggesting that H. parviporum spread may relate to the presence of heartwood. Both H. parviporum and H. annosum s.s. proved to be strong pathogens on Norway spruce; however, when competing for the same trees, H. parviporum seemed capable of excluding H. annosum s.s. from the stand.     

Species of Heterobasidion host a diverse pool of partitiviruses with global distribution and interspecies transmission

We investigated the geographic occurrence and genetic diversity of partitiviruses among 247 Heterobasidion specimens representing seven species and originating from Europe, Asia, and North America. Based on sequence analysis, partitiviruses were relatively rare, and occurred only in about 5 % of the Heterobasidion isolates analyzed, constituting a minority (about 28 %) of all virus-infected [double-stranded RNA (dsRNA)-positive] isolates. Altogether ten virus strains were characterized in sequence: one complete genome sequence of 3893 bp, six complete RNA-dependent RNA polymerase sequences of 2000-2033 bp, and three partial polymerase sequences. Based on phylogenetic analysis, the virus strains were assigned into three putative partitivirus species: HetRV1 (Heterobasidion RNA virus 1), HetRV4, and HetRV5. Degenerate consensus primers were designed for RT-PCR detection of these virus species. HetRV1 occurred in five different Heterobasidion species, and resembled the previously described Heterobasidion annosum virus (HaV). Highly similar HetRV1 strains with 98 % nucleotide level similarity were found from H. parviporum (member of the H. annosum species complex) and H. australe (member of the H. insulare complex) growing in the same region in Bhutan. This observation suggests recent virus transmission between these taxonomically distant Heterobasidion species in nature. It was also shown that HetRV1 can be transmitted by mycelial contact between the H. annosum and H. insulare complexes. The two other virus species, HetRV4 and HetRV5, were closely related to the Amasya Cherry Disease-associated mycovirus, to Heterobasidion parviporum partitivirus Fr110B, and also to several plant-infecting alphacryptoviruses. These results are in accordance with the view of a close evolutionary relationship between partitiviruses of plants and fungi.     

A novel putative partitivirus of the saprotrophic fungus Heterobasidion ecrustosum infects pathogenic species of the Heterobasidion annosum complex

We characterized the bisegmented genome of a putative double-stranded (ds) RNA virus from a Chinese isolate of the fungus Heterobasidion ecrustosum, a member of the Heterobasidion insulare species complex. The larger genomic segment of 1885bp encoded a putative RNA dependent RNA polymerase (RdRp, 585aa), and the smaller one for a putative coat protein of 521aa (1826bp). Phylogenetic analyses suggest that this novel virus species, named as 'Heterobasidion RNA virus 3 from H. ecrustosum, strain 1' (HetRV3-ec1), can be assigned to the family Partitiviridae, being most similar to the Helicobasidium mompa dsRNA mycovirus with RdRp amino acid similarity of 54%. The similarity to known viruses of other Heterobasidion species was notably low (25-39%). The virus could be experimentally transmitted to members of the Heterobasidion annosum complex: the European Heterobasidion abietinum and North American Heterobasidion occidentale, and the original host strain could be cured from the virus by thermal treatment. Microscopical observations showed that hyphae of H. ecrustosum anastomosed occasionally with H. abietinum and H. occidentale, and suggested a possible route for horizontal transmission between these sexually incompatible species. The virus infection seemed to cause variable effects on the growth rate of its fungal hosts, but the results were strongly dependent on fungal strain, growth medium and incubation temperature.     

Identification and analysis of differentially expressed cDNAs during nonself-competitive interaction between Phlebiopsis gigantea and Heterobasidion parviporum

The molecular factors regulating interspecific interaction between the saprotrophic biocontrol fungus Phlebiopsis gigantea and the conifer pathogen Heterobasidion parviporum were investigated. We constructed cDNA libraries and used expressed sequence tag analysis for the identification and characterization of genes expressed during the self and nonself-hyphal interaction. cDNA clones from either the pathogen or biocontrol agent were arrayed on nylon membrane filters and differentially screened with cDNA probes made from mycelia forming the barrage zone during nonself-interactions, mycelia growing outside the barrage zones or monocultures. BlastX analysis of the differentially expressed clones led to the identification of genes with diverse functions, including those with potential as virulence factors, such as hydrophobins. Because of the high sequence conservation (r2 = 0.81) between P. gigantea and H. parviporum, a selected number of genes from either fungus were used to monitor the expression profile under varying interaction conditions by virtual northern blot. The results are discussed with respect to the potential role of the induced genes during the nonself-competitive interaction for space and nutrients between P. gigantea and H. parviporum.     

Phylogenetic relationships of Japanese species of Heterobasidion--H. annosum sensu lato and an undetermined Heterobasidion sp

The phylogenetic relationships of two Japanese Heterobasidion species, H. annosum sensu lato and an undetermined species, were revealed based on three gene loci, glyceraldehyde 3-phosphate dehydrogenase (gpd), heat shock protein (hsp) and elongation factor 1-alpha (ef). The tree, based on combined data of gpd, hsp and ef, showed that Japanese H. annosum s.l. was close to the European S-group, forming a subclade. The results of this study also provided strong support for the recognition of the undetermined Heterobasidion sp. as a distinct phylogenetic species closely related to H. araucariae.     

Expressed sequences from the basidiomycetous tree pathogen Heterobasidion annosum during early infection of scots pine

The pattern of gene expression of the basidiomycete Heterobasidion annosum, causal agent of the root rot of conifers, was analysed during its interaction with pine roots. A complementary DNA (cDNA) library was constructed from total RNA extracted from H. annosum mycelia challenged with Scots pine seedling roots for 6 and 72h. Single pass sequencing of 1148 randomly selected cDNA clones resulted in 923 expressed sequence tags (ESTs). Contig analysis and sequence comparisons identified 318 unigene sequences, of which 62 were repeatedly sampled. A putative cellular function was assigned to 223 contigs (70%) that showed a moderate to high homology to protein sequences from public databases. Variations in expression levels during the infection process were monitored on a set of 96 unigenes by reverse northern using dot hybridisation. Seven unigenes (7%) were shown to be either up (4) or down (3) regulated during interaction of the fungus with pine roots. Fungal genes differentially expressed during contact with roots include genes encoding mitochondrial proteins, a cytochrome P450 and a vacuolar ATP synthase.     

Nuclear reassortment between vegetative mycelia in natural populations of the basidiomycete Heterobasidion annosum

Somatic incompatibility is not an absolute block to nuclear exchange between incompatible mycelia of the basidiomycete Heterobasidion annosum in vitro. Under laboratory conditions new heterokaryotic genotypes can be isolated from the gap between incompatible heterokaryons, and nuclear migration between pairs of heterokaryons grown in Petri dishes has been observed. In this study, we test the hypothesis of nuclear transfer and reassortment between heterokaryotic mycelia in natural populations of H. annosum. We developed six microsatellite markers to genotype nuclei populating 21 somatically incompatible mycelia of H. annosum isolated from a single stump of Picea abies, and found that the detected heterokaryons share nuclei; 10 of the nuclear haplotypes were found in more than one mycelium. In one isolate, four nuclear types were found in the same mycelium. These findings indicate that new heterokaryons can be formed as a result of nuclear reassortment between incompatible heterokaryotic mycelia in nature.     

Inferences on the phylogeography of the fungal pathogen Heterobasidion annosum, including evidence of interspecific horizontal genetic transfer and of human-mediated, long-range dispersal

Fungi in the basidiomycete species complex Heterobasidion annosum are significant root-rot pathogens of conifers throughout the northern hemisphere. We utilize a multilocus phylogenetic approach to examine hypotheses regarding the evolution and divergence of two Heterobasidion taxa associated with pines: the Eurasian H. annosum sensu stricto and the North American H. annosum P intersterility group (ISG). Using DNA sequence information from portions of two nuclear and two mitochondrial loci, we infer phylogenetic relationships via parsimony, Bayesian and median-joining network analysis. Analysis of isolates representative of the entire known geographic range of the two taxa results in monophyletic sister Eurasian and North American lineages, with North America further subdivided into eastern and western clades. Genetically anomalous isolates from the Italian presidential estate of Castelporziano are always part of a North American clade and group with eastern North America, upholding the hypothesis of recent, anthropogenically mediated dispersal. P ISG isolates from Mexico have phylogenetic affinity with both eastern and western North America. Results for an insertion in the mitochondrial rDNA suggest this molecule was obtained from the Heterobasidion S ISG, a taxon sympatric with the P ISG in western North America. These data are compatible with an eastern Eurasian origin of the species, followed by dispersal of two sister taxa into western Eurasia and into eastern North America over a Beringean land bridge, a pattern echoed in the phylogeography of other conifer-associated basidiomycetes.     

Heterobasidion occidentale sp. nov. and Heterobasidion irregulare nom. nov.: a disposition of North American Heterobasidion biological species

The genus Heterobasidion includes some of the most important pathogens of conifers in the world, and as such it is one of the most intensely studied genera of fungi. Because of the remarkable paucity of distinguishing morphological traits, the taxonomy of species within this genus has always been problematic. A partial resolution of the taxonomic issues regarding this genus was achieved by defining the most important and first described species within it, Heterobasidion annosum, as a species complex containing at least two partially intersterile biological species defined as intersterility groups (ISGs). With time, the number of ISGs has increased to include at least two distinct North American and three distinct Eurasian ISGs. Two additional, yet unnamed, taxonomic groups within Heterobasidion have been recently described in Japan. ISGs are distinguishable either by minor morphological differences, by partial intersterility, by ecological traits including host preference, and/or by their geographic range. Several studies employing a variety of molecular tools and analyses have confirmed the distinct genetic divergence among ISGs, identifying each of them as a monophyletic group. Using genetic markers, genotypes can always be unambiguously assigned to one ISG, and very few inter-ISG hybrids have been identified. In this paper, we summarize the available information, both genetic and ecological, that differentiates the two North American ISGs from each other and from other taxonomic units within the genus. We demonstrate that morphometric characteristics such as pore density and pore shape differentiate the two ISGs. Based on the cumulative genetic, ecological, and morphological evidence, we propose a disposition of ISGs of the North American H. annosum by replacing the P ISG with Heterobasidion irregulare, and the S ISG with Heterobasidion occidentale.     

Expression and ��-glucan binding properties of Scots pine (Pinus sylvestris L.) antimicrobial protein (Sp-AMP)

Scots pine (Pinus sylvestris) secretes a number of small, highly-related, disulfide-rich proteins (Sp-AMPs) in response to challenges with fungal pathogens such as Heterobasidion annosum, although their biological role has been unknown. Here, we examined the expression patterns of these genes, as well as the structure and function of the encoded proteins. Northern blots and quantitative real time PCR showed increased levels of expression that are sustained during the interactions of host trees with pathogens, but not non-pathogens, consistent with a function in conifer tree defenses. Furthermore, the genes were up-regulated after treatment with salicylic acid and an ethylene precursor, 1-aminocyclopropane-1-carboxylic-acid, but neither methyl jasmonate nor H(2)O(2) induced expression, indicating that Sp-AMP gene expression is independent of the jasmonic acid signaling pathways. The cDNA encoding one of the proteins was cloned and expressed in Pichia pastoris. The purified protein had antifungal activity against H. annosum, and caused morphological changes in its hyphae and spores. It was directly shown to bind soluble and insoluble β-(1,3)-glucans, specifically and with high affinity. Furthermore, addition of exogenous glucan is linked to higher levels of Sp-AMP expression in the conifer. Homology modeling and sequence comparisons suggest that a conserved patch on the surface of the globular Sp-AMP is a carbohydrate-binding site that can accommodate approximately four sugar units. We conclude that these proteins belong to a new family of antimicrobial proteins (PR-19) that are likely to act by binding the glucans that are a major component of fungal cell walls.     

Development of a rapid and simple Agrobacterium tumefaciens-mediated transformation system for the fungal pathogen Heterobasidion annosum

Heterobasidion annosum causes root and butt-rot in trees and is the most serious forest pathogen in the northern hemisphere. We developed a rapid and simple Agrobacterium-mediated method of gene delivery into H. annosum to be used in functional studies of candidate genes and for visualization of mycelial interactions. Heterobasidion annosum TC 32-1 was cocultivated at pH 5.6 and 20 degrees C in Hagems medium with Agrobacterium tumefaciens C58 carrying plasmids with hygromycin B resistance as the selectable marker and green fluorescent protein as a visual marker. We obtained 18 mitotically stable transformed isolates showing green fluorescence protein activity.     

大伏革菌防治小孔异担子菌的菌株筛选

以从芬兰引进的野生大伏革菌、中国的大伏革菌和小孔异担子菌为研究对象,通过平板对峙培养方法,从16株大伏革菌菌株中筛选出3株防治异担子菌的高效菌株,分别为:04052、08076和08077。这3号菌株具有较高的生长速率和拮抗率,能够快速覆盖病原菌,起到显著的生防效果。实验中还发现大伏革菌生长速率和拮抗率之间存在着显著的正相关关系。     

Suppression of plant defence response by a mycorrhiza helper bacterium

The aim of the present study was to determine whether the mycorrhiza helper bacterium Streptomyces sp. AcH 505 could serve as a biocontrol agent against Heterobasidion root and butt rot. Bacterial influence on mycelial growth of Heterobasidion sp. isolates, on the colonization of wood discs and Norway spruce (Picea abies) roots was determined. The effect of AcH 505 on plant photosynthesis, peroxidase activity and gene expression, and needle infections were investigated. AcH 505 was antagonistic to 11 of 12 tested fungal Heterobasidion isolates. The antagonism resulted in a suppression of fungal colonization of Norway spruce roots and wood discs. Mycelial growth rate of the 12th strain, Heterobasidion abietinum 331 was not affected by AcH 505, and colonization of roots by this fungal strain was promoted by AcH 505. Bacterial inoculation led to decreased peroxidase activities and gene expression levels in roots. AcH 505 promotes plant root colonization by Heterobasidion strains that are tolerant to antifungal metabolites produced by the bacterium. This may result from unknown bacterial factors that suppress the plant defence response.     

Molecular markers reveal genetic isolation and phylogeography of the S and F intersterility groups of the wood-decay fungus Heterobasidion annosum

The root-rot fungus Heterobasidion annosum (Fr.) Bref. species complex consists of three intersterility groups (S, F, and P), separated by their host affinity. The phylogenetic relationship of the species complex was studied, with the focus on the S and F groups, by comparing DNA sequences of four nuclear gene fragments: calmodulin, glyceraldehyde 3-phosphate dehydrogenase, heat stress protein 80-1, and elongation factor 1-alpha, and one anonymous locus, from 29 fungal isolates originating from Europe, Asia, and North America. The phylogeny of each separate gene locus as well as the combined dataset consisted of three main clades: European F group isolates, Euroasian S group isolates, and North American S group isolates, suggesting them to be separated into phylogenetic species. The results also support the hypothesis of an early separation between the S and F groups, indicating that their distribution have followed their host tree species for a considerable time period.