Pangola grass colonized with Scytalidium thermophilum for production of Agaricus bisporus

This work had the dual objective of selecting a substrate for rapid mycelial growth of Scytalidium thermophilum and then comparing the growth and production of a brown variety of Agaricus bisporus on substrate non-colonized and colonized with S. thermophilum. Mycelial growth of S. thermophilum at 45 degrees C was significantly greater on potato dextrose yeast extract agar (0.58 mm/h) as compared to malt extract glucose agar (0.24 mm/h) and yeast extract glucose agar (0.44 mm/h). On cereal grain, S. thermophilum grew significantly faster on rice (0.31 mm/h) compared to sorghum (0.22 mm/h) and millet (0.18 mm/h). It also grew faster on Pangola grass (0.49 mm/h) compared to corncobs (0.30 mm/h) and sawdust (0.18 mm/h). Colonization of Pangola grass with S. thermophilum was influenced by the addition of calcium salts in the form of gypsum, hydrated lime and ground limestone. For production of A. bisporus, biological efficiency (BE) on pasteurized Pangola grass pre-colonized by S. thermophilum for 4 days at 45 degrees C was more than twice (26.4%) that on grass non-colonized by S. thermophilum (11.0%). The addition of 2% hydrated lime to Pangola grass prior to colonization by S. thermophilum resulted in an additional doubling of BE of mushroom production (48.1%). These results show the possibility of developing a non-composted substrate method for producing A. bisporus without autoclaving the substrate.     

Growth-promoting effect of thermophilic fungi on the mycelium of the edible mushroom Agaricus bisporus.

The growth-promoting effect of the thermophilic fungus Scytalidium thermophilum in mushroom compost on the mycelium of the edible mushroom Agaricus bisporus was investigated. Results obtained by others were confirmed by showing that S. thermophilum leads to an increased hyphal extension rate of the mushroom mycelium. However, it was demonstrated that hyphal extension rates were not clearly related to mushroom biomass increase rates. A number of experiments pointed strongly towards CO2 as the determinant of hyphal extension rates. In compost, CO2 is produced mainly by thermophilic fungi. Several experiments did not reveal any other specific compound produced by S. thermophilum that increases the hyphal extension rate of the mushroom mycelium.     

Growth-promoting effect of thermophilic fungi on the mycelium of the edible mushroom Agaricus bisporus.

The growth-promoting effect of the thermophilic fungus Scytalidium thermophilum in mushroom compost on the mycelium of the edible mushroom Agaricus bisporus was investigated. Results obtained by others were confirmed by showing that S. thermophilum leads to an increased hyphal extension rate of the mushroom mycelium. However, it was demonstrated that hyphal extension rates were not clearly related to mushroom biomass increase rates. A number of experiments pointed strongly towards CO2 as the determinant of hyphal extension rates. In compost, CO2 is produced mainly by thermophilic fungi. Several experiments did not reveal any other specific compound produced by S. thermophilum that increases the hyphal extension rate of the mushroom mycelium.     

蘑菇培养料堆制过程中微生物的演替及作用

蘑菇培养料堆制的完成依赖于微生物群落共同作用来实现。综述了堆制阶段培养料中细菌、放线菌、真菌三大类型菌群出现、发展的规律 ,各自作用特点以及它们之间的相关性、拮抗性 ,同时从呼吸途径、酶学角度阐述了嗜热真菌对料选择性的形成和蘑菇菌丝生长的积极意义。     

Identification of indole derivatives as self-growth inhibitors of Symbiobacterium thermophilum, a unique bacterium whose growth depends on coculture with a Bacillus sp

Symbiobacterium thermophilum is a syntrophic bacterium whose growth depends on coculture with a Bacillus sp. Recently, we discovered that CO(2) generated by Bacillus is the major inducer for the growth of S. thermophilum; however, the evidence suggested that an additional element is required for its full growth. Here, we studied the self-growth-inhibitory substances produced by S. thermophilum. We succeeded in purifying two substances from an ether extract of the culture supernatant of S. thermophilum by multiple steps of reverse-phase chromatography. Electron ionization mass spectrometry and nuclear magnetic resonance analyses of the purified preparation identified the substances as 2,2-bis(3'-indolyl)indoxyl (BII) and 1,1-bis(3'-indolyl)ethane (BIE). The pure growth of S. thermophilum was inhibited by authentic BII and BIE with MICs of 12 and 7 microg/ml, respectively; however, its growth in coculture with Bacillus was not inhibited by BII at the saturation concentration and was inhibited by BIE with an MIC of 14 microg/ml. Both BII and BIE inhibited the growth of other microorganisms. Unexpectedly, the accumulation levels of both BII and BIE in the pure culture of S. thermophilum were far lower than the MICs (<0.1 microg/ml) while a marked amount of BIE (6 to 7 microg/ml) equivalent to the MIC had accumulated in the coculture. An exogenous supply of surfactin alleviated the sensitivities of several BIE-sensitive bacteria against BIE. The results suggest that Bacillus benefits S. thermophilum by detoxifying BII and BIE in the coculture. A similar mechanism may underlie mutualistic relationships between different microorganisms.     

Transglycosylation activity of Dictyoglomus thermophilum amylase A

Amylase A from Dictyoglomus thermophilum is a thermophilic enzyme and has about 40% identity with 4-alpha-glucanotransferase (GTase) from Thermococcus litoralis, and both of these enzymes belong to family 57 glycosyl hydrolase. Since the transglycosylation activity of T. litoralis GTase has been well characterized, the substrate specificity and reaction products of amylase A from D. thermophilum were examined. alpha-1,4 Glucan was produced from maltooligosaccharides, and glucoamylase-resistant molecules (cycloamyloses) were produced from longer chain amylose (average molecular mass 200 kDa). It has been reported that amylase A from D. thermophilum hydrolyzes starch, but in this study it was found that the enzyme was also able to use maltooligosaccharides and long chain amylose as substrate and has transglycosylation activity.     

Cloning, expression, and characterization of novel thermostable family 7 cellobiohydrolases

As part of the effort to find better cellulases for bioethanol production processes, we were looking for novel GH-7 family cellobiohydrolases, which would be particularly active on insoluble polymeric substrates and participate in the rate-limiting step in the hydrolysis of cellulose. The enzymatic properties were studied and are reported here for family 7 cellobiohydrolases from the thermophilic fungi Acremonium thermophilum, Thermoascus aurantiacus, and Chaetomium thermophilum. The Trichoderma reesei Cel7A enzyme was used as a reference in the experiments. As the native T. aurantiacus Cel7A has no carbohydrate-binding module (CBM), recombinant proteins having the CBM from either the C. thermophilum Cel7A or the T. reesei Cel7A were also constructed. All these novel acidic cellobiohydrolases were more thermostable (by 4-10 degrees C) and more active (two- to fourfold) in hydrolysis of microcrystalline cellulose (Avicel) at 45 degrees C than T. reesei Cel7A. The C. thermophilum Cel7A showed the highest specific activity and temperature optimum when measured on soluble substrates. The most effective enzyme for Avicel hydrolysis at 70 degrees C, however, was the 2-module version of the T. aurantiacus Cel7A, which was also relatively weakly inhibited by cellobiose. These results are discussed from the structural point of view based on the three-dimensional homology models of these enzymes.     

Lessons from studies of Symbiobacterium thermophilum, a unique syntrophic bacterium

Symbiobacterium thermophilum is a syntrophic bacterium whose growth depends on coculture with a cognate Bacillus sp. We have been studying the unique features of S. thermophilum in terms of taxonomy, ecology, genome biology, and physiology. Here we overview current knowledge of this bacterium. Although S. thermophilum shows several physiological properties of Gram-negative bacteria, 16S rRNA gene-based phylogeny indicated that it represents a distinct lineage of Gram-positive bacteria with deep branching between the clades for the high-G+C (Actinobacteria) and the low-G+C (Firmicutes) groups. Ecological study has revealed that S. thermophilum and its relatives are widely distributed in the natural environment, including soil, animal intestines and seawater. A whole genome sequencing study uncovered its unusual features, which overall indicate that this bacterium is a member of Firmicutes despite of its high G+C content (68.7%). The genome appeared to retain fully the genes for primary metabolism, except for carbonic anhydrase. We discovered that carbon dioxide is a marked inducer of the mono-growth of S. thermophilum, and speculated that this is due to a lack of carbonic anhydrase. The lines of evidence suggest that S. thermophilum requires additional conditions for full growth, including not only the supply of an unknown positive factor but also the elimination of oxygen and self-growth inhibitory substances. We conclude that the role of the cognate Bacillus is to establish a complex environment suitable for the growth of S. thermophilum, which is achieved by supplying and removing multiple factors. Understandings of this type of mutualism should provide new insight into microbial physiology as well as the issue of uncultivability.     

Efficient GFP expression in the mushrooms Agaricus bisporus and Coprinus cinereus requires introns

We have developed a "Molecular Toolkit" comprising interchangeable promoters and marker genes to facilitate transformation of homobasidiomycete mushrooms. We describe the evaluation of a range of promoters in the homobasidiomycetes Agaricus bisporus and Coprinus cinereus using green fluorescent protein (GFP) as a reporter gene; the C. cinereus trp1 promoter and A. bisporus trp2 and gpdII promoters proving successful in driving expression in C. cinereus, with the gpdII promoter also functioning in A. bisporus. Our investigations demonstrate that a prerequisite for GFP expression in C. cinereus and A. bisporus is the presence of an intron. This is the first reported expression of GFP in either C. cinereus or A. bisporus.     

Cloning of a gene encoding thermostable cellobiohydrolase from the thermophilic fungus Chaetomium thermophilum and its expression in Pichia pastoris

Aims:  A new cellobiohydrolase (CBH) gene ( cbh3 ) from Chaetomium thermophilum was cloned, sequenced and expressed in Pichia pastoris .
Methods and Results:  Using RACE-PCR, a new thermostable CBH gene ( cbh3 ) was cloned from C. thermophilum . The cDNA of the CBH was 1607 bp and contained a 1356 bp open reading frame encoding a protein CBH precursor of 451 amino acid residues. The mature protein structure of C. thermophilum CBH3 only comprises a catalytic domain and lacks cellulose-binding domain and a hinge region. The gene was expressed in P. pastoris . The recombinant CBH purified was a glycoprotein with a size of about 48·0 kDa, and exhibited optimum catalytic activity at pH 5·0 and 60 °C. The enzyme was more resistant to high temperature. The CBH could hydrolyse microcrystalline cellulose and filter paper.
Conclusions:  A new thermostable CBH gene of C. thermophilum was cloned, sequenced and overexpressed in P. pastoris .
Significance and Impact of the Study:  This CBH offers an interesting potential in saccharification steps in both cellulose enzymatic conversion and alcohol production.     

Development of a membrane dialysis bioreactor and its application to a large-scale culture of a symbiotic bacterium,Symbiobacterium thermophilum

A simple membrane dialysis bioreactor was developed for a large-scale axenic culture of Symbiobacterium thermophilum, a symbiotic thermophile that requires co-cultivation with an associating thermophilic Bacillus strain S for normal growth. The bioreactor consisted of an outer- and an inner-coaxial cylindrical compartment bordered across a dialyzing membrane, which enabled a 1 l-scale dialysis culture with exchange of low molecular metabolites between the two compartments to be performed. Using the bioreactor, growth characteristics of S. thermophilum and Bacillus strain S were assessed under two medium conditions. The growth of S. thermophilum was measured by quantitative PCR because the bacterium formed no visible colonies and gave abnormally low turbidity. In medium containing 2% tryptone peptone, S. thermophilum proliferated up to 4x10(7) cells/ml, and strict dependence on the co-culture with Bacillus strain S was observed. On the other hand, medium containing 0.5% yeast extract not only facilitated the growth of S. thermophilum in the co-culture (6x10(7) cells/ml), but also allowed limited pure growth independent of Bacillus strain S (1x10(7) cells/ml), implying that some component of yeast extract can partially replace the growth requirement of S. thermophilum supplied by Bacillus strain S. Both the oxidative redox potential values and the cell morphology in the independently growing culture suggested the occurrence of marked unbalanced growth possibly caused by significant metabolic changes. The bioreactor is applicable to the analyses of culturing characteristics in symbiotic systems between free-living microorganisms.     

Establishing the independent culture of a strictly symbiotic bacterium Symbiobacterium thermophilum from its supporting Bacillus strain.

Symbiobacterium thermophilum is a strictly symbiotic thermophile, the growth of which is dependent on the coexistence of an associating thermophilic Bacillus sp., strain S. S. thermophilum grows only in mixed culture with the Bacillus strain in liquid media, and does not form visible colonies on solid media. To measure the growth of this symbiotic bacterium and to analyze its growth requirements, we developed a quantitative PCR method by using its specific sequences in a putative membrane translocator gene tnaT as primers. According to this method, independent growth of S. thermophilum was first confirmed in a dialyzing culture physically separated from Bacillus strain S with a cellulose membrane. Independent growth of S. thermophilum was also managed by adding conditioned medium prepared from the culture filtrate of the Bacillus strain, but the growth in the conditioned medium stopped at a very limited extent with appearance of filamentous cells, suggesting the uncoupling of cellular growth and cell division. Formation of micro-colonies of S. thermophilum was observed on the conditioned agar medium under both aerobic and anaerobic conditions, but the colony-forming efficiencies remained below 1%. Several other bacterial species, such as Bacillus stearothermophilus, Bacillus subtilis, Thermus thermophilus, and even Escherichia coli, were also found to support the growth of S. thermophilum. These results indicate that S. thermophilum essentially requires some ubiquitous metabolite(s) of low molecular weight produced by various bacterial species as growth factor(s) but coexistence of the living partner cells is still required, probably to maintain an effective level of the putative factor(s) in the medium.     

Verticillium disease or "dry bubble" of cultivated mushrooms: the Agaricus bisporus lectin recognizes and binds the Verticillium fungicola cell wall glucogalactomannan

The step of recognition and (or) binding for the development of the disease of the cultivated mushroom Agaricus bisporus by the mycoparasite Verticillium fungicola was studied by several approaches: agglutination of V. fungicola germinated spores by an A. bisporus extract from fruit body cell walls, immunofluorescence microscopy of A. bisporus hyphae from fruit bodies and vegetative mycelia pretreated with purified V. fungicola cell wall glucogalactomannan, and finally, by hemagglutination experiments carried out with an A. bisporus fruit body lectin in the presence and absence of the same glucogalactomannan. Hemagglutinating activity of the purified A. bisporus fruit body lectin was clearly inhibited by the V. fungicola glucogalactomannan, whereas in the A. bisporus vegetative mycelium such lectin was not encountered. All the results obtained make evident the recognition and binding of the A. bisporus fruit body lectin to the V. fungicola cell wall glucogalactomannan, clarifying why the mushrooms, but not the vegetative mycelium, become diseased.     

Diversity in the ability of Agaricus bisporus wild isolates to fruit at high temperature (25°C)

The button mushroom Agaricus bisporus commercially cultivated requires 16-19 °C during the fruiting period. Wild strains are also present in natural habitat, and in light of their wide range of geographic distribution reported, from boreal region to tropical region, questions on the development adaptation to temperature arose. Isolates from various geographic areas were screened for their ability to fruit at higher temperature (FHT ability) than commercial cultivars. The FHT trait discriminated at the varietal rank. Agaricus bisporus var. eurotetrasporus was unable to develop any sporophores whilst A. bisporus var. burnettii adapted perfectly to 25 °C for fruiting, suggesting that the FHT ability is a fixed trait in these varieties. In contrast, FHT ability of A. bisporus var. bisporus appeared variable and correlated neither with climate/microclimate nor with habitat. However, FHT ability taken as a whole appeared higher in North American populations than in European ones. Some A. bisporus var. bisporus isolates revealed a good potential for cultivation at 25 °C.     

有害疣孢霉菌与双孢蘑菇的互作关系

通过菌丝对峙、双重培养,以及对发病双孢蘑菇子实体的显微观察,探讨有害疣孢霉菌Mycogone perniciosa（MP0012）与双孢蘑菇Agaricus bisporus（As2796）之间的互作关系。结果表明,在菌丝对峙生长阶段有害疣孢霉菌菌丝不侵入双孢蘑菇菌丝体内,两者可交叉生长,对双孢蘑菇生长影响不显著;对峙与双重培养均显示有害疣孢霉菌菌丝会产生对双孢蘑菇菌丝生长的抑制作用的挥发性物质,造成双孢蘑菇菌丝扭结断裂。同时试验证实了双孢蘑菇菌丝会促进有害疣孢霉菌厚垣孢子的产生和萌发、菌丝生长和发育。侵染实验结果表明,有害疣孢霉菌可直接侵染双孢蘑菇子实体,引起双孢蘑菇子实体病害;对罹病子实体显微观察结果发现,发病前期双孢蘑菇子实体表面长出绒毛状病原菌丝,菌柄中空,菌褶褐变腐烂并长出病原菌丝;发病中期双孢蘑菇子实体内菌丝组织会出现萎缩裂解现象,在近有害疣孢霉菌菌丝一侧的双孢蘑菇子实体菌丝细胞壁被降解;发病后期双孢蘑菇子实体菌丝组织基本消失。由此初步判断有害疣孢霉菌对双孢蘑菇的寄生类型偏向于死体营养型。     

Towards reconstructing a metabolic tree of life

Using information from several metabolic databases, we have built our own metabolic database containing 434 pathways and 1157 different enzymes. We have used this information to construct a dendrogram that demonstrates the metabolic similarities between 282 species. The resulting species distribution and the clusters defined in the tree show a certain taxonomic congruence, especially in recent relationships between species. This dendrogram is another representation of the tree of life, based on metabolism that may complement the trees constructed by other methods. For example, the metabolic dissimilarity we demonstrate between Symbiobacterium thermophilum (previously defined as Actinobacteria) and the other Actinobacteria species, and the metabolic similarity between S. thermophilum and Clostridia, combined with other evidence, suggest that S. thermophilum may be re-classified as Firmicutes, Clostridia.     

Ultrastructural analysis and identification of envelope proteins of "Candidatus Chloracidobacterium thermophilum" chlorosomes

Chlorosomes are sac-like, light-harvesting organelles that characteristically contain very large numbers of bacteriochlorophyll (BChl) c, d, or e molecules. These antenna structures occur in chlorophototrophs belonging to some members of the Chlorobi and Chloroflexi phyla and are also found in a recently discovered member of the phylum Acidobacteria, "Candidatus Chloracidobacterium thermophilum." "Ca. Chloracidobacterium thermophilum" is the first aerobic organism discovered to possess chlorosomes as light-harvesting antennae for phototrophic growth. Chlorosomes were isolated from "Ca. Chloracidobacterium thermophilum" and subjected to electron microscopic, spectroscopic, and biochemical analyses. The chlorosomes of "Ca. Chloracidobacterium thermophilum" had an average size of ～100 by 30 nm. Cryo-electron microscopy showed that the BChl c molecules formed folded or twisted, sheet-like structures with a lamellar spacing of ～2.3 nm. Unlike the BChls in the chlorosomes of the green sulfur bacterium Chlorobaculum tepidum, concentric cylindrical nanotubes were not observed. Chlorosomes of "Ca. Chloracidobacterium thermophilum" contained a homolog of CsmA, the BChl a-binding, baseplate protein; CsmV, a protein distantly related to CsmI, CsmJ, and CsmX of C. tepidum, which probably binds a single [2Fe-2S] cluster; and five unique polypeptides (CsmR, CsmS, CsmT, CsmU, and a type II NADH dehydrogenase homolog). Although "Ca. Chloracidobacterium thermophilum" is an aerobe, energy transfer among the BChls in these chlorosomes was very strongly quenched in the presence of oxygen (as measured by quenching of fluorescence emission). The combined analyses showed that the chlorosomes of "Ca. Chloracidobacterium thermophilum" possess a number of unique features but also share some properties with the chlorosomes found in anaerobic members of other phyla.     

Isolation and characterization of Ferroplasma thermophilum sp. nov., a novel extremely acidophilic, moderately thermophilic archaeon and its role in bioleaching of chalcopyrite

Aims:  To isolate Ferroplasma thermophilum L1^T from a low pH environment and to understand its role in bioleaching of chalcopyrite.
Methods and Results:  Using serial dilution method, a moderately thermophilic and acidophilic ferrous iron-oxidizing archaeon, named L1^T, was isolated from a chalcopyrite-leaching bioreactor. The morphological, biochemical and physiological characteristics of strain L1^T and its role in bioleaching of chalcopyrite were studied. Strain L1^T was a nonmotile coccus that lacked cell wall. Strain L1^T had a temperature optimum of 45°C and the optimum pH for growth was 1·0. Strain L1^T was capable of chemomixotrophic growth on ferrous iron and yeast extract. Results of fatty acid analysis, DNA–DNA hybridization, G+C content, and analysis based on 16S rRNA gene sequence indicated that strain L1^T should be grouped in the genus Ferroplasma , and represented a new species, Ferroplasma thermophilum . Ferroplasma thermophilum in combination with Acidithiobacillus caldus and Leptospirillum ferriphilum could improve the copper dissolution in bioleaching of chalcopyrite.
Conclusions:  A novel extremely acidophilic, moderately thermophilic archaeon isolated from a bioleaching reactor has been identified as F. thermophilum that played an important role in bioleaching of chalcopyrite at low pH.
Significance and Impact of the Study:  This study contributes to understand the characteristics of F. thermophilum L1^T and its role in bioleaching of sulfide ores.     

双孢蘑菇基因组密码子的偏好性分析

双孢蘑菇Agaricus bisporus是世界上最广泛栽培的食用菌之一。本研究通过分析双孢蘑菇基因组密码子使用偏性,探讨密码子偏性的影响因素及其对基因表达的影响。以双孢蘑菇基因组和转录组数据为依据,分析了双孢蘑菇基因组基因、高表达基因（high expression gene,HEG）和低表达基因（low expression gene,LEG）的密码子使用性。发现双孢蘑菇基因组编码基因平均GC含量为49.08%,T3s值（35.59%）最高,平均ENC值偏高,多数基因表达潜力较低。共鉴定出14个最优密码子,均以C或T结尾,并且遵循密码子中嘌呤和嘧啶使用的均衡性原则。高表达基因具有更强的密码子偏性,进化过程中受到基因突变和自然选择等多种因素影响。基因表达与G/C碱基含量和CAI值呈极显著正相关。高表达基因编码了多种与真菌生长发育相关的蛋白和酶类。研究结果明确了双孢蘑菇基因密码子的使用偏性,为双孢蘑菇转基因育种和品质改良提供了参考。