Trichoderma amazonicum, a new endophytic species on Hevea brasiliensis and H. guianensis from the Amazon basin

A new species of Trichoderma (teleomorph Hypocrea, Ascomycota, Sordariomycetes, Hypocreales, Hypocreaceae), T. amazonicum, endophytic on the living sapwood and leaves of Hevea spp. trees is described. Trichoderma amazonicum is distinguished from closely related species in the Harzianum clade (e.g. Hypocrea alni, H. brunneoviridis, H. epimyces, H. parepimyces, T. aggressivum, T. harzianum, T. pleuroticola and T. pleuroti) by morphological and ecological characteristics and phylogenetic analysis of three loci (ITS nrDNA, tef1 and rpb2). The closest relatives of this species are the facultatively fungicolous species T. pleuroticola and T. pleuroti.     

Molecular identification of Trichoderma species associated with Pleurotus ostreatus and natural substrates of the oyster mushroom

Green mold of Pleurotus ostreatus , caused by Trichoderma species, has recently resulted in crop losses worldwide. Therefore, there is an emerging need for rapid means of diagnosing the causal agents. A PCR assay was developed for rapid detection of Trichoderma pleurotum and Trichoderma pleuroticola , the two pathogens causing green mold of P. ostreatus . Three oligonucleotide primers were designed for identifying these species in a multiplex PCR assay based on DNA sequences within the fourth and fifth introns in the translation elongation factor 1α gene. The primers detected the presence of T. pleurotum and/or T. pleuroticola directly in the growing substrates of oyster mushrooms, without the need for isolating the pathogens. The assay was used to assess the presence of the two species in natural environments in which P. ostreatus can be found in Hungary, and demonstrated that T. pleuroticola was present in the growing substrates and on the surface of the basidiomes of wild oyster mushrooms. Other Trichoderma species detected in these substrates and habitats were Trichoderma harzianum, Trichoderma longibrachiatum and Trichoderma atroviride. Trichoderma pleurotum was not found in any of the samples from the forested areas tested in this study.     

Trichoderma harzianum metabolites pre-adapt mushrooms to Trichoderma aggressivum antagonism

Trichoderma spp. is the cause of green mold, a disorder that affects cultivated mushrooms. The aims of the study were to establish whether improvement of mushroom resistance to Trichoderma aggressivum could be obtained by inducing reaction mechanisms before contact with the pathogen and whether this ability was species or strain dependent. Twenty nine isolates of Agaricus bisporus, 29 isolates of Lentinula edodes and 18 isolates of Pleurotus spp. were studied. The effect of T. harzianum metabolites on mycelial growth of these isolates was evaluated on YMEA (yeast, malt extract and agar), supplemented or not with Lysing Enzymes from T. harzianum (Sigma?, L1412). Mycelial growth generally was affected by Lysing Enzymes, but some L. edodes and Pleurotus spp. adapted to Lysing Enzymes. When mycelium was taken from a first culture with Lysing Enzymes and placed on YMEA with Lysing Enzymes for a second culture, their growth rate was not different from those of the controls. In the case of A. bisporus, only partial adaptation was obtained with a few isolates. The effect of adaptation to Lysing Enzymes on resistance to T. aggressivum was assayed for one strain of each group. Trichoderma aggressivum was exposed to the margin of 5- to 9-day-old mushroom colonies. Agaricus bisporus produced brown droplets, and T. aggressivum overgrew its mycelium. Lentinula edodes and P. ostreatus produced brown lines blocking the progression of T. harzianum, both on YMEA and YMEA plus Lysing Enzymes. The line was visible after 3 d on YMEA and after only 2 d on YMEA plus Lysing Enzymes. Improvement in the resistance to antagonists by introduction of some of their metabolites to the culture medium is a method for mushroom protection.     

木霉属中国新纪录种Trichoderma pleuroticola和T. pleurotum

【目的】对蔬菜大棚土壤中和阿魏菇腐烂的菌盖上分离的两株木霉菌进行分类鉴定。【方法】结合形态学分类特征和ITS序列分析的方法进行鉴定。【结果】从蔬菜大棚的土壤中和阿魏菇腐烂的菌盖上分离的两株木霉菌分别为Trichoderma pleuroticola和T.pleurotum。T.pleuroticola的形态特征与T.harzianum相似,但其分生孢子显著大于T.harzianum的分生孢子,且在PDA上产生黑褐色的色素以及黄色的结晶物。T.pleurotum典型特征是分生孢子梗单生,有时匍匐,分枝散生,初级分枝和分生孢子梗顶端聚生,类似粘帚霉。【结论】分离的两株木霉分别是T.pleuroticola和T.pleurotum,为木霉菌中国新纪录种。     

Chitinase production during interaction of Trichoderma aggressivum and Agaricus bisporus

The competitor fungus Trichoderma aggressivum causes green mould disease, a potentially devastating problem of the commercial mushroom Agaricus bisporus. Due to the recent appearance of this problem, very little is known about the mechanisms by which T. aggressivum interacts with and inhibits A. bisporus. A mechanism generally used by Trichoderma species in the antagonism of other fungi is the secretion of cell wall degrading enzymes. In this study, we determined the activities of chitinases produced in dual cultures of these fungi over a 2 week period. Both intracellular and extracellular enzymes were studied. Agaricus bisporus produced N-acetylglucosaminidases with apparent molecular masses of 111, 105, and 96 kDa. Two resistant brown strains produced greater activities of the 96 kDa N-acetylglucosaminidase than susceptible off-white and white strains. This result suggested that this enzyme might have a role in the resistance of commercial brown strains to green mould disease. Trichoderma aggressivum produced three N-acetylglucosaminidases with apparent molecular masses of 131, 125, and 122 kDa, a 40 kDa chitobiosidase, and a 36 kDa endochitinase. The 122 kDa N-acetylglucosaminidase showed the greatest activity and may be an important predictor of antifungal activity.     

Two new species of <Emphasis Type="Italic">Trichoderma</Emphasis> from Yunnan,China

Two new species of the fungal genus Trichoderma, Trichoderma compactum and Trichoderma yunnanense, isolated from rhizosphere of tobacco in Yunnan Province, China are described based on morphological characters and phylogenetic analyses of nucleotide sequences. Our DNA sequences included the internal transcribed spacer (ITS) regions of the rDNA cluster (ITS1 and ITS2), and partial sequences of the translation elongation factor 1-alpha (tef1) and a fragment of the gene coding for endochitinase 42 (ech42). The analyses show that T. compactum belongs to the Harzianum clade, and T. yunnanense belongs to the Hamatum clade.     

Taxonomy and phylogenetic relationships of two species of Hypocrea with Trichoderma anamorphs

Hypocrea patella is reevaluated. Its Trichoderma anamorph is described and the phylogenetic position of the species is determined through sequences of the ITS regions of rDNA. It is sister to a clade that includes Trichoderma longibrachiatum/H. schweinitzii. Hypocrea patella f. tropica is accepted for a Costa Rican collection. Hypocrea neorufa and its Trichoderma anamorph are described. Its phylogenetic position is determined by sequences of the ITS region of rDNA and the protein-coding translation-elongation factor (EF-1α). It is derived from within a clade that includes T. viride/H. rufa, T. atroviride/H. atroviridis, T. koningii/H. koningii and T. asperellum. Deceased August 2002.     

洞庭湖湿地木霉多样性及生防活性

【目的】了解湖南省洞庭湖湿地木霉种类及分布,丰富我国的木霉种质资源,为功能菌株筛选应用奠定基础。【方法】利用ITS序列比对分析结合形态学特征对分离到的木霉菌株进行种类鉴定,构建系统发育进化树分析其亲缘关系。通过菌丝生长速率法测定菌株的平板抑菌能力,根据水解带大小检测菌株的水解酶活性,利用灰色关联度分析筛选综合生防效果较好的木霉菌株。【结果】从52个土样和18个水样中分离得到114株木霉菌株,经鉴定分属16个木霉种类:哈茨木霉、绿木霉、刺孢木霉、土星孢木霉、钩状木霉、拟康宁木霉、短密木霉、深绿木霉、猥木霉、毛细木霉(中国新记录种)、长枝木霉、卵孢木霉、侧耳木霉、加纳木霉、厚木霉及一个疑似新种;哈茨木霉为洞庭湖湿地中的优势种,占总菌株数量的19.30%;16种木霉在系统发育树中归于7个进化支:Harzianum Clade、Virens Clade、Longibrachiatum Clade、Lutea Clade、Viride Clade、Hamatum Clade、Unknown Clade。灰色关联度分析表明,菌株TW21990、QT22040和QT22094的灰色关联度较高,分别为0.849 5、0.798 6和0.732 6,综合生防性状较好。【结论】洞庭湖湿地木霉具有种类多样性和分布多样性,发现了一个中国新记录种毛细木霉和一个疑似新种,哈茨木霉TW21990、长枝木霉QT22040和卵孢木霉QT22094是潜在的优良生防菌株。     

木霉属Trichoderma组和Pachybasium组的分子系统学研究

对来源不同的木霉及其有性型Longibrachiatum组、Trichoderma 组和Pachybasium组的81个菌株进行了ITS序列测定,并对ITS1序列用PHYLIP程序包中的DNAPARS程序进行系统发育分析。结果表明Trichoderma 组和Pachybasium组的所有菌株可分成两个群(A,B),B群进一步分为4个分支(B1,B2,B3,B4);A群由Trichoderma 组的H. aureoviridis和未鉴定到种的3个Hypocrea菌株构成;B1,B2,B4群均由Pachybasium组菌株构成;B3群由Pachybasium组的T. hamatum、T. strigosum和Trichoderma 组的T. asperellum、T. atroviride、T. koningii、T. viride和Hypocrea菌株T261构成。2个组相互交叉,组间没有明确的区分,进一步证明Pachybasium组是多系的。建议将Trichoderma 组中的T. viride aggr.、T. atroviride、T. koningii归并入Pachybasium组,对Trichoderma 组重新定义。     

Molecular characterization and identification of biocontrol isolates of Trichoderma spp

The most common biological control agents (BCAs) of the genus Trichoderma have been reported to be strains of Trichoderma virens, T. harzianum, and T. viride. Since Trichoderma BCAs use different mechanisms of biocontrol, it is very important to explore the synergistic effects expressed by different genotypes for their practical use in agriculture. Characterization of 16 biocontrol strains, previously identified as "Trichoderma harzianum" Rifai and one biocontrol strain recognized as T. viride, was carried out using several molecular techniques. A certain degree of polymorphism was detected in hybridizations using a probe of mitochondrial DNA. Sequencing of internal transcribed spacers 1 and 2 (ITS1 and ITS2) revealed three different ITS lengths and four different sequence types. Phylogenetic analysis based on ITS1 sequences, including type strains of different species, clustered the 17 biocontrol strains into four groups: T. harzianum-T. inhamatum complex, T. longibrachiatum, T. asperellum, and T. atroviride-T. koningii complex. ITS2 sequences were also useful for locating the biocontrol strains in T. atroviride within the complex T. atroviride-T. koningii. None of the biocontrol strains studied corresponded to biotypes Th2 or Th4 of T. harzianum, which cause mushroom green mold. Correlation between different genotypes and potential biocontrol activity was studied under dual culturing of 17 BCAs in the presence of the phytopathogenic fungi Phoma betae, Rosellinia necatrix, Botrytis cinerea, and Fusarium oxysporum f. sp. dianthi in three different media.     

Hypocrea atroviridis sp. nov., the teleomorph of Trichoderma atroviride

A new species, Hypocrea atroviridis, is described for the teleomorph of Trichoderma atroviride. Based on sequences of ITS-1, 5.8S, and ITS-2 regions of the rDNA complex and translation-elongation factor (EF-1α), T. atroviride and H. atroviridis form a well-supported clade within Trichoderma sect. Trichoderma. The conserved anamorphic phenotype of T. atroviride, observed for both conidial and ascospore derived cultures, was only found within that clade. In contrast, the teleomorph phenotype of H. atroviridis was morphologically indistinguishable from H. rufa, the teleomorph of T. viride. This Hypocrea phenotype may, therefore, be considered to be plesiomorphic within Trichoderma sect. Trichoderma, suggesting that genes controlling the expression of the teleomorph and anamorph evolve at different rates and that the genes controlling expression of the teleomorph are more conserved than are those controlling the expression of the anamorph.     

Hypocrea voglmayrii sp. nov. from the Austrian Alps represents a new phylogenetic clade in Hypocrea/Trichoderma

The holomorph of the new species Hypocrea voglmayrii (Hypocreales, Ascomycota, Fungi) is described by a combined approach, using morphology of the teleomorph, morphology of the anamorph, culture studies and phylogenetic analyses of ITS1 and 2, ech42 and rpb2 gene sequences. Its anamorph Trichoderma voglmayrii is described as a new anamorph species. Unlike most other species of Hypocrea the teleomorph of H. voglmayrii occurs on dry standing trunks and exhibits well defined black ostioles. Although exclusively collected at higher altitudes, this species grows at 35 C in culture. Hypocrea voglmayrii develops pale yellowish to greenish conidia, a yellowish pigment and a coconut-like odor on CMD. Phylogenetically, H. voglmayrii forms a distinct, isolated branch between the section Trichoderma and the H. pachybasioides clade but does not associate with any of these clades in different gene trees.     

Hypocrea peltata: a mycological Dr Jekyll and Mr Hyde?

Hypocrea peltata (Pezizomycotina, Hypocreales, Hypocreaceae) is a common, widespread essentially subtropical species, with an uncharacteristically large stroma and asci containing four large and four small bicellular ascospores. Its only anamorph consists of indehiscent aleuriospores; it does not form a Trichoderma anamorph, which is typical of most Trichoderma/Hypocrea species. Hypocrea peltata grows very well at 37 C. The large stromata and failure to form a Trichoderma anamorph could lead one to doubt its generic placement. However sequences of the internal transcribed spacer region (ITS), 28S nuclear large subunit (LSU) of rDNA and RNA polymerase subunit II (rpb2) regions indicate that it represents a unique lineage within Trichoderma/Hypocrea. ITS and rbp2 sequences derived from cultures of H. peltata are identical to the "unidentified Hypocreaceae" reported in the literature as being isolated from lung of a patient with non-fatal pulmonary fibrosis.     

An oligonucleotide barcode for species identification in Trichoderma and Hypocrea

One of the biggest obstructions to studies on Trichoderma has been the incorrect and confused application of species names to isolates used in industry, biocontrol of plant pathogens and ecological surveys, thereby making the comparison of results questionable. Here we provide a convenient, on-line method for the quick molecular identification of Hypocrea/Trichoderma at the genus and species levels based on an oligonucleotide barcode: a diagnostic combination of several oligonucleotides (hallmarks) specifically allocated within the internal transcribed spacer 1 and 2 (ITS1 and 2) sequences of the rDNA repeat. The barcode was developed on the basis of 979 sequences of 88 vouchered species which displayed in total 135 ITS1 and 2 haplotypes. Oligonucleotide sequences which are constant in all known ITS1 and 2 of Hypocrea/Trichoderma but different in closely related fungal genera, were used to define genus-specific hallmarks. The library of species-, clade- and genus-specific hallmarks is stored in the MySQL database and integrated in the TrichOKey v. 1.0 - barcode sequence identification program with the web interface located on . TrichOKey v. 1.0 identifies 75 single species, 5 species pairs and 1 species triplet. Verification of the DNA-barcode was done by a blind test on 53 unknown isolates of Trichoderma, collected in Central and South America. The obtained results were in a total agreement with phylogenetic identification based on tef1 (large intron), NCBI BLAST of vouchered records and postum morphological analysis. We conclude that oligonucleotide barcode is a powerful tool for the routine identification of Hypocrea/Trichoderma species and should be useful as a complement to traditional methods.     

PCR-based genotyping of epidemic and preepidemic Trichoderma isolates associated with green mold of Agaricus bisporus.

We used randomly amplified polymorphic DNA (RAPD)-PCR to estimate genetic variation among isolates of Trichoderma associated with green mold on the cultivated mushroom Agaricus bisporus. Of 83 isolates examined, 66 were sampled during the recent green mold epidemic, while the remaining 17 isolates were collected just prior to the epidemic and date back to the 1950s. Trichoderma harzianum biotype 4 was identified by RAPD analysis as the cause of almost 90% of the epidemic-related episodes of green mold occurring in the major commercial mushroom-growing region in North America. Biotype 4 was more closely allied to T. harzianum biotype 2, the predominant pathogenic genotype in Europe, than to the less pathogenic biotype 1 and Trichoderma atroviride (formerly T. harzianum biotype 3). No variation in the RAPD patterns was observed among the isolates within biotype 2 or 4, suggesting that the two pathogenic biotypes were populations containing single clones. Considerable genetic variation, however, was noted among isolates of biotype 1 and T. atroviride from Europe. Biotype 4 was not represented by the preepidemic isolates of Trichoderma as determined by RAPD markers and PCR amplification of an arbitrary DNA sequence unique to the genomes of biotypes 2 and 4. Our findings suggest that the onset of the green mold epidemic in North America resulted from the recent introduction of a highly virulent genotype of the pathogen into cultivated mushrooms.     

Hypocrea/Trichoderma species with pachybasium-like conidiophores: teleomorphs for T. minutisporum and T. polysporum and their newly discovered relatives

We describe or redescribe species of Hypocrea/Trichoderma (Ascomycetes, Hypocreales) having hyaline ascospores and pachybasium-like conidiophores. Teleomorphs are reported for Trichoderma minutisporum (Hypocrea minutispora sp. nov.) and T. polysporum (H. pachybasioides). Hypocrea pilulifera/T. piluliferum is redescribed. Trichoderma croceum is synonymized with T. polysporum. The new species H. parapilulifera, H. stellata and H. lacuwombatensis are described. All of these species fall within the morphological concept of Trichoderma sect. Pachybasium and within the phylogenetic group pachybasium B5 of Kullnig-Gradinger et al (2002). Parsimony analysis of nucleotide sequences from three unlinked loci-ITS1 and 2, endochitinase (ech42) and translation elongation factor 1-alpha (tef1)-detects two distinct phylogenetic lineages within the group pachybasium B5. One comprises H. pachybasioides/T. polysporum, H. pilulifera/T. piluliferum, H. parapilulifera and H. stellata; this group, the "polysporum" lineage, is characterized by having conidia that are white in mass and is the only lineage within Hypocrea characterized by such conidia. The second group includes the green conidial T. minutisporum and H. lacuwombatensis. The partition homogeneity test reveals significant recombination within the "polysporum" lineage but not within the "minutisporum" lineage.     

Isolate-specific conidiation in Trichoderma in response to different nitrogen sources

A characteristic feature of Trichoderma is the production of concentric rings of conidia in response to alternating light/dark conditions and a single ring of conidia in response to a single burst of light. In this study, conidiation was investigated in four biocontrol isolates (T. hamatum, T. atroviride, T. asperellum, T. virens) and one isolate from the mushroom pathogen species, T. pleuroticola. All five isolates produced concentric conidial rings under alternating light/dark conditions on potato-dextrose agar (PDA), however, in response to a 15min burst of blue light, only T. asperellum and T. virens produced a clearly defined conidial ring. Both T. pleuroticola and T. hamatum photoconidiated in a disk-like fashion and T.?atroviride produced a broken ring with a partially filled in appearance. In the presence of primary nitrogen, T. asperellum and T. pleuroticola conidiated in a disk, whereas, when grown in the presence of secondary nitrogen, a ring of conidia was produced. Primary nitrogen promoted photoconidiation and competency to conidiate in response to light appeared dependent on the nitrogen catabolite repression state of the cell. Mycelial injury was also investigated in the same five isolates of Trichoderma on PDA and under different nitrogen statuses. For the first time, we report that conidiation in response to injury is differentially regulated in different isolates/species of Trichoderma.     

Thermal requirement for development of Sancassania rodionovi (Acari: Acaridae) on mushrooms

The free-living mite species Sancassania rodionovi (Zachvatkin) (Acari: Acaridae), is a serious pest of mushrooms in Iran. Studies were conducted to examine the development of this mite in relation to temperature on two mushroom species: Agaricus bisporus Lange (button mushroom) and Pleurotus ostreatus Kummer (oyster mushroom). The developmental time of this acarid mite was studied at eight constant temperatures, ranging from 5 to 40 degrees C, and developmental rates were modeled as a function of temperature. Sancassania rodionovi completed immature development in 17.35 +/- 0.58 and 20.17 +/- 0.88 d at 25 degrees C on button and oyster mushrooms, respectively. When the mite fed on button mushroom, the rate of development increased gradually from 10 to 35 degrees C. Using a linear model, the developmental zero was estimated to be 3.50 degrees C with a thermal constant of 357.14 degree-days. The Logan 10, Briere 1, and Thermodynamic models adequately described the data for this mite and yielded R2 values >0.95; these models provided estimates of optimum temperature for development of 33.244, 32.145, and 32.148 degrees C, respectively. Understanding the influence of temperature on development of S. rodionovi is discussed with respect to pest management in mushroom production.