黄孢原毛平革菌抗营养阻遏产漆酶同工酶动态分析

以选育的抗营养阻遏产木质素降解酶黄孢原毛平革菌（Phanerochaete chrysosporium）pcR5305、pcR5324为实验对象,研究了其在富氮条件下动态产漆酶同工酶的规律及其可能的营养调控机制。两菌株可在初始氨氮质量浓度达2.2 g/L的富氮环境下产漆酶,启动漆酶合成及达到产酶峰值对应的葡萄糖、氨氮浓度阀值远高于野生型,基质C/N的降低是漆酶合成启动及达到高峰的前提,其中碳浓度的降低更为重要。两菌株在不同时间可产生1～3种漆酶同工酶（分别为Lac1、Lac2和Lac3）,其中Lac3产酶伴随菌体整个生长过程,其合成启动与积累无需受基质碳氮饥饿及C/N的限制;Lac2在pcR5305初生代谢阶段产生,但只能在pcR5324次生代谢阶段产生;Lac1仅在pcR5305的初生代谢或次生代谢阶段产生,基质C/N降至5.0～7.0时诱导产生 Lac1的合成,并随培养时间的增加产酶量逐渐提高。显然3种同工酶的合成具有不同的调控机制。     

黄孢原毛平革菌突变株抗碳氮营养阻遏产漆酶碳氮生理调控机理

【目的】通过比较不同碳氮营养及其消耗对产漆酶的影响,了解白腐菌模式种黄孢原毛平革菌解除营养阻遏产漆酶代谢的生理生态特性,揭示白腐菌合成漆酶的碳氮生理调控机理。【方法】分别利用限碳限氮(CL-NL)、限碳富氮(CL-NS)、富碳限氮(CS-NL)与富碳富氮(CS-NS)4种条件培养黄孢原毛平革菌野生型(WT)与突变株,比较两者产漆酶动力学、菌体生长、葡萄糖与氨氮消耗差异及其相关性来揭示解除营养阻遏产漆酶调控生理特性,明确C、N营养对产漆酶的生理调控途径。【结果】突变菌株除消耗速率比野生型略慢外,两者氨消耗趋势一致,但对葡萄糖的消耗比野生型快且氨氮浓度对葡萄糖的消耗影响不大。在CL-NL、CL-NS、CS-NL、CS-NS 4种培养条件下,野生型分别在培养后期的第11、14、19和19天的次生代谢时期产生0.107、0.029、12.84和18.05U/L漆酶,启动漆酶合成及酶峰值出现的时间与基质中葡萄糖耗尽或接近耗尽的时刻,或同氨氮消耗至最低值的时刻相对应;与WT产漆酶特性不同,突变株产漆酶伴随整个培养过程且均有两个产酶高峰,分别在培养的第8、7、12天和12天出现298.83、343.14、271.22、251.49U/L漆酶第一个产酶高峰,在培养的第12、13、19和19天产生257.69、298.78、213.81、216.93U/L漆酶的第二个产酶高峰。碳氮营养对产酶的影响显示:两菌株只要初始碳源浓度相同(限碳或富碳),各自产酶动力学趋势基本一致;相反,即使初始氮源浓度相同但其产酶动力学趋势却不同,说明碳源对黄孢原毛平革菌产漆酶的影响比氮源更为重要。【结论】野生型黄孢原毛平革菌产漆酶受碳或氮饥饿调控,碳、氮各自独立发挥作用且在不同的营养条件下由不同营养素所调控,如在限碳条件下产漆酶主要由葡萄糖饥饿启动,而在富碳条件下则由氨氮饥饿所激发,以碳或氮菌体负荷表示是否达到启动酶合成的调控阀值比单纯碳或氮浓度更为合理。突变菌株漆酶合成的启动不受碳、氮营养所阻遏,可能涉及一个全局调控的改变,解除了漆酶合成的营养阻碍。     

黄孢原毛平革菌产漆酶优化培养及其对刚果红的脱色降解

以白腐真菌模式菌株黄孢原毛平革菌Phanerochaete chrysosporium为研究对象,探讨培养条件、重金属和芳香族化合物对产漆酶的影响,并进一步研究漆酶对刚果红的降解效果.结果 表明,P.chrysosporium产漆酶最适培养条件:葡萄糖为碳源,蛋白胨为氮源,碳氮比为90.培养8d后,漆酶酶活为911.1...     

黄孢原毛平革菌合成木素过氧化物酶的营养调控

本文研究了营养条件对黄孢原毛平革茵(Phanerochale chrysosporium)ME-116合成木素过氧化物酶及其同工酶组分的影响.在最适培养条件下获得1500U/L的酶活.高效液相色谱分离的5个同工酶组分中以P_2组分含量最高.低碳高氮培养基最适于酶的合成.降低氮和KH_2PO_4含量致使各组分含量下降,而改变MgSO_4和CaCl_2浓度对P_2组分无影响.表面活性剂吐温80主要通过提高细胞膜透性而增加酶的合成.黎芦醇对5种同工酶组分的合成均有诱导作用.培养基中各营养因子对木素过氧化物酶的合成存在着复杂的交互作用.     

黄孢原毛平革菌产絮凝剂营养条件优化

微生物絮凝剂与传统化学絮凝剂相比,安全无毒、无二次污染,具有开发潜力.黄孢原毛平革菌(Phanerochaete chrysosporium)能产生微生物絮凝剂,但目前缺少对其产絮凝剂营养条件的优化.使用高岭土并利用单因素法研究碳源、氮源、碳氮比、接种量对Phanerochaete chrysosporium产絮凝剂的...     

黄孢原毛平革菌生产锰过氧化物酶的发酵条件研究

目的 :研究黄孢原毛平革菌产锰过氧化物酶的发酵条件。方法 :对培养条件进行优化 ,采用正交设计法对培养基组分进行优化。结果与结论 :优化培养条件为 :接种量 1 6× 10 6 个孢子 L ,pH 4 4～ 4 8,温度 36℃～ 4 0℃ ,转数 12 0r/min。优化培养基参数为 :葡萄糖 5g L ,酒石酸铵 1 3mmol L ,吐温 - 80 1 2g L ,Mn2 + 0 9mmol L。     

黄孢原毛平革菌木素降解酶系的研究进展

黄孢原毛平革菌木素降解酶系主要由木素过氧化物酶、锰过氧化物酶和乙二醛氧化酶组成。由于该酶系特殊的降解机制,除了木质素,它能降解许多种类的有机污染物,因此在环保方面有巨大的应用前景。本文主要综述了国内外对该酶系的研究进展。     

一氧化氮在启动黄孢原毛平革菌木质素降解酶合成中的作用

[目的]通过了解一氧化氮在启动黄孢原毛平革菌合成木质素过氧化物酶(LiP)中的作用及其作用机制,弄清白腐菌启动次生代谢的调控机制.[方法]以黄孢原毛平革菌原种pc530及突变种pcR5305为研究对象,弄清在不同营养条件下NO含量的动态变化及其与合成LiP之间的关系,再通过添加外源NO供体SNP、NO淬灭剂cPTIO对两菌株合成LiP的影响分析,揭示NO在白腐菌启动合成LiP中的作用和作用机理.[结果]两菌株均能在两种不同营养条件下产生NO,但NO的产生量与菌株及其营养状况有关,富营养使pc530产生NO量低且严重延后,而pcR5305产生NO并不需要营养饥饿激发且产生量显著高于pc530.除了LiP峰值出现时间迟于NO峰值时间外,NO含量与LiP合成呈正相关性;外施SNP对合成LiP有促进作用,但对pcR5305的促进作用没有pc530明显;15 mmol/L cPTIO使黄孢原毛平革菌合成LiP均大为降低,但并没有完全抑制产生LiP.[结论]黄孢原毛平革菌可能通过产生NO启动LiP的合成,但NO并不直接参与或影响合成LiP,NO更可能是作为一种上游的信号分子起作用.除了NO外,可能还有其它与NO有相互促进作用的信号分子也参与了LiP合成的调控.与pc530具有不同的产生NO的机制可能就是pcR5305抗营养阻遏合成木质素降解酶的机理.     

黄孢原毛平革菌木质素过氧化物酶基因在甲醇毕赤酵母中的表达

将编码黄孢原毛平革菌木质素过氧化物酶(lip)的cDNA克隆到酵母整合型质粒pMETA上,电转化Ade缺陷型甲醇毕赤酵母(Pichiamethanolica)PMAD16,通过MD平板及PCR方法筛选和鉴定重组子。重组子发酵液经SDSPAGE分析和木质素过氧化物酶活力测定等方法鉴定,表明带自身信号肽的黄孢原毛平革菌木质素过氧化物酶基因(lip)在甲醇毕赤酵母中得到表达。优化其发酵培养条件,以藜芦醇为底物进行酶活测定,其酶活可达932U/L。相应发酵指数为12.94U/h·L。比出发菌株提高了24.18%。     

黄孢原毛平革菌木素过氧化物酶类在天然木素降解中作用的研究

通过诱变得到十一株木素过氧化物酶酶活降低的黄孢原毛平革菌（Ｐｈａｎｅｒｏｃｈａｅｔｅｃｈｒｙｓｏｓｐｏｒｉｕｍ）突变株,用灰色理论分析了其木素过氧化物酶类的产生与木素降解能力间的相关性,并从中筛选到一株木素过氧化物酶缺陷、锰过氧化物酶酶活明显降低的突变株,其木素降解能力为原始菌株的８０％左右。该菌粗酶液作用于纤维素酶酶解杉木木素和天然褐腐木素,可产生小分子的木素降解产物,此反应不需Ｈ２Ｏ２参与。红外光谱分析表明粗酶液对木素的作用主要为氧化作用,因此推测此突变株粗酶液中含有不同于木素过氧化物酶和锰过氧化物酶的与木素氧化降解有关的酶类     

Solid-state fermentation of natural birch lignin by Phanerochaete chrysosporium

A strain of white rot fungus, Phanerochaete chrysosporium Burds. ME446, has been characterized with respect to the extent and rate of Betula nigrificans lignin and non-lignin conversion by solid-substrate fermentation for different culture conditions. Moisture content, inoculum density, nitrogen supplementation and autoclaving of birch solids significantly affected lignin conversion rates and yields in 20 day fermentations. Oxygen favoured lignin over non-lignin conversion at partial pressures of 1.0 atm. Oxygen pressures of 2.0 atm severely inhibited both lignin and non-lignin conversions. Carbon dioxide partial pressures of 0.25, 0.5 and 1.0 atm at oxygen pressures of 1.0 atm increasingly inhibited both lignin and non-lignin conversion rates and yields. The results of these studies demonstrate the effects of major process variables and suggest a need to control the gas environment for process optimization.     

黄孢原毛皮革菌降解苯胺的工艺研究

通过正交试验优化筛选了适合黄孢原毛皮革菌降解苯胺的适宜培养基和摇瓶培养降解条件。结果表明：其适宜降解的液体培养基组成为：蔗糖20g／L,可溶性淀粉20g／L,(NH4)2SO4l0g／L,Mn^2 lμmol／L,Tween-800．3％,蛋白胨30g／L。适宜降解的摇瓶培养条件为：接种量为20％、pH为7．0、温度为30℃、培养时间为12d．此条件下的苯胺最高降解率可达95．5％。     

Polymerisation of lignins by ligninases from Phanerochaete chrysosporium

Abstract Four major hemoproteins were purified by isoelectric focusing from an extracellular crude enzyme preparation, produced by the white rot fungus Phanerochaete chrysosporium under carbon-limited conditions. Both the crude enzyme and the purified proteins oxidised milled wood lignin, HCl-dioxane-extracted straw lignin and alkali straw lignin in the presence of hydrogen peroxide. The oxidation resulted mainly in further polymerisation of the lignins and was enhanced by addition of veratryl alcohol to the reaction mixture. Alkali straw lignin was also polymerised by horseradish peroxidase, although veratryl alcohol had no influence on this reaction.     

Diuron degradation by Phanerochaete chrysosporium BKM- F-1767 in synthetic and natural media

When incubated in synthetic (N-limited) medium and on ashwood chips, Phanerochaete chrysosporium BKM-F-1767 degraded 14 and 10 mg/l diuron, respectively. The wood chips were used as support and sole nutrient source for the fungus. A higher degradation efficiency was found in ashwood culture as compared to the liquid culture, probably as a result of the synergetic effect of attached fungal growth, presence of limiting-substrate conditions and the microenvironment provided by ashwood, all favorable for production of high extracellular enzyme titres. Diuron degradation occured during the idiophasic growth, in the presence of manganese peroxidase, detected as dominant enzyme in both cultures.     

Mineralization of biphenyl and PCBs by the white rot fungus Phanerochaete chrysosporium

The white rot fungus Phanerochaete chrysosporium is unique in its ability to totally degrade a wide variety of recalcitrant pollutants. We have investigated the degradation of biphenyl and two model chlorinated biphenyls, 2,2',4,4'-tetrachlorobiphenyl and 2-chlorobiphenyl by suspended cultures of P. chrysosporium grown under conditions that maximize the synthesis of lignin-oxidizing enzymes. Radiolabeled biphenyl and 2'-chlorobiphenyl added to cultures at concentrations in the range 260 nM to 8.8 muM were degraded extensively to CO(2) within 30 days. In addition, from 40% to 60% of the recovered radioactivity was found in water-soluble compounds. A correlation between the rate of degradation and the synthesis of ligninases or Mn-dependent peroxidases could not be observed, indicating that yet unknown enzymatic system may be resonsible for the initial oxidation of PCBs. The more heavily chlorinated PCB congener, 2,2',4,4'-tetrachlorobiphenyl was converted to CO(2) less readily; approximately 9% and 0.9% mineralization was observed in cultures incubated with 40 nM and 5.3 muM, respectively. Overall, our results indicate that P. chrysosporium is a promising organism for the treatment of wastes contaminatd with lightly and moderately chlorinated PCBs. (c) 1992 John Wiley & Sons, Inc.