褐腐真菌产生的低分子化合物对纤维素的解聚作用研究

糙皮侧耳（Ｐｌｅｕｒｏｔｕｓｏｓｔｒｅａｔｕｓ）密粘褶菌（Ｇｌｏｅｏｐｈｙｌｌｕｍｔｒａｂｅｕｍ）洁丽香菇（Ｌｅｎｔｉｎｕｓｌｅｐｉｄｅｕｓ）等８株褐腐菌在滤纸上进行固体培养时,在培养初期,纤维素的聚合度均呈现大幅度下降,但不表现失重。培养过程中也未能检测出滤纸酶活力,只有少量内切葡聚糖酶活力。而且这８株菌都具有络合Ｆ３＾３＋和产生羟基自由基,ＯＨ的能力,由降解和解聚能力最强的密粘褶菌的胞外酶液在     

褐腐真菌纤维素降解初期产生羟基自由基的普遍性研究*

本文通过对11株褐腐菌的研究,发现其普遍具有产生HO的特性;而且于褐腐菌的胞外培养液中均得到了部分分离纯化的、非酶的III组分,III组分普遍具有还原Fe3+为Fe2+的能力。III组分对纤维素底物的作用实验表明,HO的氧化机制在褐腐菌对纤维素降解的初期普遍存在,HO氧化断裂纤维素链内或链间的氢键,继而断裂糖苷键,使纤维素暴露出更多的还原性和非还原性末端,为纤维素酶的进一步降解提供有利条件。     

褐腐真菌木质纤维素降解机制的研究进展

褐腐菌降解木才机理的研究日前受到关注,发现褐腐菌不具有对结晶纤维素降解十分重要的外切葡聚糖酶,而以一种独特的方式解降纤维素。近年来,关于其以自由基氧化降解机制进行作用的报道很多,并且各国研究工作从褐腐菌中分离得到了不同性质的物质,提出了羟基自由基HO．循环形成的各种假说,但褐腐菌降木材的确切机制仍未搞清楚,这些分离得到的具有一些特殊性质的胞外物质在降解中的作用还有待于证明,在此。对近年来褐腐菌纤维素降解机制的研究进展作一简单介绍。     

褐腐真菌木质纤维素降解机制的研究进展*

褐腐菌降解木材机理的研究日益受到关注 ,发现褐腐菌不具有对结晶纤维素降解十分重要的外切葡聚糖酶 ,而以一种独特的方式降解纤维素。近年来 ,关于其以自由基氧化降解机制进行作用的报道很多 ,并且各国研究工作者从褐腐菌中分离得到了不同性质的物质 ,提出了羟基自由基HO·循环形成的各种假说 ,但褐腐菌降解木材的确切机制仍未搞清楚 ,这些分离得到的具有一些特殊性质的胞外物质在降解中的作用还有待于证明。在此 ,对近年来褐腐菌纤维素降解机制的研究进展作一简单介绍。     

密粘褶菌胞外低分子量多肽在纤维素降解中作用的研究

从褐腐真菌中能强烈降解纤维素的代表菌株密粘褶菌(Gloeophyllum trabeum)的胞外酶液中首次分离纯化得到一低分子量的活性多肽组分(称作Gt因子),此组分能在有O.2和Fe³⁺存在时产生羟基自由基HO·;对纤维素降解的研究表明,Gt因子不同于纤维素酶对纤维素的β1.4糖苷键的水解作用,而以HO·氧化的途径作用于纤维素,导致纤维素中氢键的断裂,降低纤维素的结晶度,使其暴露出更多的末端,从而有利于纤维素的进一步降解。     

褐腐真菌产生的羟基自由基HO˙对纤维素作用的研究

由褐腐真菌的典型菌株——密粘褶菌Gloeophyllum trabeum的胞外培养液中分离纯化得到一能还原Fe3 ,产生羟基自由基HO˙的多肽组分(称作Gt因子)。 采用HO˙特异性的抑制剂硫脲,对Gt因子产生的HO˙在纤维素降解中的作用进行了对照研究,结果表明Gt因子及其产生的HO˙在纤维素降解中起着重要的作用,为褐腐菌HO˙氧化降解纤维素机制假说的确立提供了一些依据。     

密粘褶菌Gloeophyllum trabeum胞外低分子量多肽的分离纯化及其对纤维素生物降解作用

通过HPLC高效液相层析由褐腐真菌中能强烈降解木质纤维素的代表菌株密粘褶菌Gloeo phyllumtrabeum的胞外培养液 ,分离纯化得到一低分子量的活性多肽组分 (Gt因子 ) .Gt因子具有较好热稳定性 ,在pH 2 5～ 6 5范围内保持稳定 .Gt因子分子量在 4 0 0 0左右 ,等电点pI 6 6 .Gt因子具有络合Fe3 + 的能力 ,且能够将Fe3 + 还原为Fe2 + .在O2 存在时 ,能以纤维素物质为电子供体形成羟基自由基HO·.利用循环伏安法 ,观察到Gt因子与纤维素底物之间的氧化还原过程 .研究表明 ,Gt因子极有可能在褐腐菌的纤维素降解初期起着重要的作用 .     

褐腐真菌产生的羟基自由基HO˙对纤维素作用的研究*

由褐腐真菌的典型菌株——密粘褶菌Gloeophyllum trabeum的胞外培养液中分离纯化得到一能还原Fe3+,产生羟基自由基HO˙的多肽组分(称作Gt因子)。 采用HO˙特异性的抑制剂硫脲,对Gt因子产生的HO˙在纤维素降解中的作用进行了对照研究,结果表明Gt因子及其产生的HO˙在纤维素降解中起着重要的作用,为褐腐菌HO˙氧化降解纤维素机制假说的确立提供了一些依据。     

不同木质纤维素基质上白腐菌降解特性的研究

通过测定木质素、纤维素、半纤维素和漆酶分泌的变化,研究白腐菌在稻草、木屑、粗纤维素、滤纸、黑液木素基质上的降解特性。结果表明,除黑液木素上白腐菌不能生长外,在前25d,各基质中纤维素、半纤维素和木质素含量呈持续下降趋势,之后,降解速率减少,其中木质素的降解速率大于纤维素和半纤维素的降解速率。漆酶分泌在生长初期呈快速上升趋势,第10d酶活达到最大,第10～20d快速下降,其后基本不变,基质中酶活大小顺序为稻草基质、木屑基质、粗纤维和滤纸基质,显示了木质素存在对漆酶分泌的诱导作用。     

Function of a low molecular peptide generated by cellulolytic fungi for the degradation of native cellulose

Peptides (MW < 5 kDa) produced by 57 cellulolytic fungi can form free radicals. Scanning tunneling microscopy (STM) and IR spectroscopy showed that the peptide produced by Trichoderma pseudokoningii can break the hydrogen bond network of cellulose. The synergic action of these peptides and cellulases increased production of reducing sugars during degradation of native cellulose.     

Basic studies and applications on bioremediation of DDT: A review

The persistent insecticide DDT (1,1,1-trichloro-2,2-bis (4-chlorophenyl) ethane) has been widely used for pest control in the management of mosquito-borne malaria and is still used for that purpose in some tropical countries. Considering the potential for negative effects due to DDT contamination, it is necessary to determine effective methods of remediation. Several methods have been used to degrade or transform DDT into less toxic compounds. Bacteria and white-rot fungi (WRF) have been shown to enhance the degradation process in soil using both pure and mixed cultures. Recently, a biological approach has been used as an environmentally-friendly treatment, using new biological sources to degrade DDT, e.g. brown-rot fungi (BRF), cattle manure compost (CMC) and spent mushroom waste (SMW). In this review, the abilities of BRF, CMC and SMW to degrade DDT are discussed, including the mechanisms and degradation pathways. Furthermore, application of these sources to contaminated soil is also described. The review discusses which is the best source for bioremediation of DDT.     

Ergosterol contents of some wood-rotting basidiomycete fungi grown in liquid and solid culture conditions

Ergosterol contents of six wood-rotting basidiomycetes were analyzed under different cultivation conditions. Four white-rot and two brown-rot fungi were cultivated in liquid synthetic medium with low nutrient nitrogen (2 mM) and 0.1% glucose, and ergosterol in mycelial biomasses were measured weekly for 35 days. The highest ergosterol content per fungal dry mass in the white-rot fungi was found in Phanerochaete chrysosporium being 2100 μg g⁻¹, while in Ceriporiopsis subvermispora it was 1700 μg g⁻¹, Phlebia radiata 700 μg g⁻¹, and Physisporinus rivulosus 560 μg g⁻¹. In brown-rot fungi the ergosterol content was in Poria placenta 2868 μg g⁻¹ and in Gloeophyllum trabeum 3915 μg g⁻¹. On agar media, P. chrysosporium and P. radiata reached the highest ergosterol value in 7 days, while in wood block cultures the ergosterol contents were quite stable. The conversion factors for ergosterol-to-fungal biomass varied from 48 and 243, which were lower than values for ascomycetous soil fungi reported in the literature.     

Catabolism of 1,2-diarylethane lignin model compounds by two brown-rot fungi

The catabolism of dimethoxybenzil, anisoin and hydroanisoin in nitrogen-limited stationary cultures of the brown-rot fungi Wolfiporia cocos and Gloeophyllum trabeum was analyzed. These three 1,2-diarylethane lignin model compounds, which differ in the degree of oxidation of the alkylic chain, gave rise to p-anisaldehyde in both cultures, suggesting that cleavage between the two aliphatic carbons had occurred. In turn, both strains reduced dimethoxybenzil and anisoin to hydroanisoin, whereas only Wolfiporia cocos was able to oxidize hydro-anisoin to anisoin. On the other hand, chemically derived hydroxyl radical, but not superoxide radical, produced p-anisaldehyde plus other unidentified compounds from anisoin and hydroanisoin. Neither radical modified dimethoxybenzil significantly.Abbreviations HGLN high glucose, low nitrogen - HGHN high glucose, high nitrogen - HPLC high performance liquid chromatography - TLC thin layer chromatography - A anisoin - HA hydroanisoin - DMB dimethoxybenzil - OH Hydroxyl radical - O _inf2 ^sup- superoxide radical     

Detection of metal-chelating compounds from wood-rotting fungi Trametes versicolorand Wolfiporia cocos

For many years, the wood decay process by fungi was associated almost exclusively with production of lignocellulolytic enzymes. However, recent studies by electron microscopy have shown that fungal enzymes are too large to penetrate into the cell wall at an early stage of decay. Thus, the hypothesis that low molecular mass agents may initiate the breakdown of both cellulose and lignin was proposed. The purpose of this work was to detect low molecular mass compounds, with metal-chelating capability, from liquid cultures of two wood-rot fungi. The brown-rot fungus Wolfiporia cocos produced the highest chrome azurol S (CAS) reaction, simultaneously reducing the pH of the malt extract medium. In contrast, the white-rot fungus Trametes versicolor did not react with CAS and the pH remained approximately constant during the culture period. The presence of hydroxamate derivatives and oxalic acid was detected in extracts of low molecular mass of both fungi. Moreover, in W. cocos extracts, catecholate derivatives were also detected. Accumulation of oxalic acid was greater in W. cocos than in T. versicolor at the end of the culture period, and this might be responsible for the strong response from W. cocos in the CAS reaction.     

Bioremediation of DDT contaminated soil using brown-rot fungi

The ability of brown-rot fungi (BRF) to eliminate DDT in artificially and historically contaminated soil was investigated to determine whether the BRF would be suitable for the bioremediation of DDT in soil. Gloeophyllum trabeum, Fomitopsis pinicola and Daedalea dickinsii showed an ability to eliminate DDT in artificially contaminated sterilized (SL) and un-sterilized (USL) soils. The addition of Fe²⁺ to the soil system enhanced the ability of some BRF to eliminate DDT. In the contaminated SL soil, the DDT was eliminated by approximately 41%, 9% and 15% by G. trabeum, F. pinicola and D. dickinsii, respectively. Compared with the controls, in the USL soil approximately 43%, 29% and 32% of DDT was eliminated and approximately 20%, 9% and 26% of DDD (1,1-dichloro-2,2-bis (4-chlorophenyl) ethane) was detected as a metabolic product with G. trabeum, F. pinicola and D. dickinsii, respectively. Of the BRF, G. trabeum demonstrated the greatest ability to eliminate DDT both in the SL and USL soils. G. trabeum was applied to a historically contaminated soil which had a DDT concentration more than three times the artificially contaminated soil. G. trabeum remediated about 64% of the initial DDT with the addition of Fe²⁺. There were no significant differences in the results with or without the addition of Fe²⁺, indicating that G. trabeum can be used directly for the degradation of DDT in soil without any other additional treatment. This study identified that G. trabeum is the most promising BRF for use in the bioremediation of DDT contaminated soil.     

Enzymes and small molecular mass agents involved with lignocellulose degradation

Abstract: Electron microscopic and biochemical studies of lignocellulose degradation by wood-rotting fungi have shown that enzymes such as lignin peroxidases, manganese-dependent peroxidases, laccases and cellulases are too large to penetrate undegraded secondary wood cell walls. Degradation occurs by surface interaction between cell wall and enzymes, but initiation of decay at a distance from the fungal hyphae must involve diffusible low-molecular mass agents. The roles of hydrogen peroxide, veratryl alcohol, oxalate, Fe²⁺-Fe³⁺ and Mn²⁺-Mn³⁺, as such agents in lignocellulose degradation are discussed.