共查询到19条相似文献,搜索用时 160 毫秒
1.
以白腐真菌的中的黄孢原毛平革菌(Phanerochaete chrysosporium)为实验菌种,考察不同环境条件因素对P.chrysosporium降解磷酸三苯酯(TPhP)的影响以及TPhP降解过程中菌体细胞特性的变化.结果表明,当孢子液的接种量为4%(V/V),葡萄糖浓度为5g/L,pH值为5~6时,经过6d的处理P.chrysosporium对5mg/L TPhP的降解率可达到60%以上.菌体的细胞色素P450酶在TPhP的降解转化过程中发挥了重要的作用,抑制P450酶的活性会导致TPhP降解率下降.在降解反应的前期,为加快TPhP的代谢转化,菌体胞内蛋白含量以及ATP酶活性出现明显升高.在TPhP胁迫下,菌体SOD和CAT的活性随降解反应的进行呈现先升高后降低的趋势,2种抗氧化酶协同作用维持TPhP降解过程中菌体胞内的氧化还原平衡. 相似文献
2.
Mn^2+在黄杆菌FCN2菌株降解芘过程中的作用研究 总被引:2,自引:0,他引:2
利用紫外分光光度法和原子吸收分光光度法研究了Mn2 在菌株FCN2生长细胞,悬浮细胞、粗酶液降解芘时的影响作用.在菌体生长期加入0.1~5mmol/L的Mn2 ,对菌体的生长及生长量无影响,但对芘的降解均有促进作用,以加入0.1mmol/L的Mn2 效果最好,其对芘的平均降解率是对照的1.26倍.此时菌株富集的Mn2 为0.025mmol/L;在用无外加Mn2 培养的菌株PCN2悬浮细胞降解芘时,加入0.5mmol/L的Mn2 ,芘的平均降解率为对照的1.67倍.降解反应发生72h后菌株富集的Mn2 为0.18mmol/L;在酶促降解时加入0.1mmol/L Mn2 ,平均降解率为对照的1.30倍.结果表明,在不同时期加入的Mn2 对降解芘均有一定的促进作用. 相似文献
3.
考察短短芽胞杆菌(Brevibacillus brevis)菌体及芽胞对四环多环芳烃芘的降解性能.结果表明,菌体5 d内对1 mg·L-1芘的降解率可达53%.菌体和胞内酶降解芘过程中检测到1-羟基芘、9-羟基菲、α-萘酚和β-萘酚这4种单羟基降解产物,在完整菌体降解体系中,产物呈现先积累后下降的趋势,而在胞内粗酶液降解体系中,大分子代谢产物表现为一直积累的趋势,说明B.brevis完整菌体在降解初期并不具备一些中间产物的降解酶,但随着时间推移,可被诱导产生相关酶对生成的新产物进行进一步降解.芽胞悬液在添加芘的无机盐培养基中5 d内萌发生成的营养细胞可达到1.5×109个·L-1,对1 mg·L-1芘的降解率达到15%. 相似文献
4.
白腐菌锰过氧化物酶对2,2’,4,4’-四溴联苯醚的降解 总被引:1,自引:0,他引:1
多溴联苯醚(PBDEs)是一类在环境中普遍存在的全球性有机污染物,对这类污染物环境行为的研究虽然已有较多报道,但是微生物降解方面尤其是针对单一胞外酶降解的研究还比较少。文章以白腐菌模式菌种Phanerochaete chrysosporium为对象,研究其分泌的胞外酶锰过氧化物酶(MnP)对环境中最常检测到的2,2’,4,4’-四溴联苯醚(BDE47)的好氧降解,考察不同β-环糊精浓度对该酶降解BDE47的影响,并初步探讨了胞内细胞色素P450的作用。结果表明,MnP能有效降解BDE47,在培养15 d后,扣除空白损失,降解率达到70%左右。低浓度和高浓度的环糊精对MnP降解BDE47无显著性影响。胞内细胞色素P450对BDE47的降解没有明显贡献。 相似文献
5.
将1.0g/L的微囊藻毒素-LR(MC-LR)降解菌恶臭假单胞菌(Pseudomonas putida)置于含不同浓度MC-LR的体系中,研究了体系中菌体细胞完整性和生物量的变化,考察了MC-LR对细胞的氧化胁迫以及抗氧化酶的响应.结果表明,MC-LR能够增大P. putida细胞质膜通透性,造成膜损伤,导致胞内物质外流,使细胞完整性遭到破坏;同时,MC-LR能够引起P. putida细胞的氧化胁迫,随着毒素暴露时间的延长,活性氧自由基(ROS)和膜脂过氧化产物丙二醛(MDA)含量显著升高,具有明显的剂量效应.超氧化物歧化酶(SOD)活性在MC-LR的诱导下有一个先升后降的过程,表现为对低浓度污染物的主动响应,而高浓度(2.5 mg/L)MC-LR作用5d后,ROS积累到相当高水平,对细胞代谢功能造成破坏,使SOD活性下降,并加速细胞的死亡,P. putida生物量与对照相比,下降了将近50%. 相似文献
6.
生物转化是影响有机污染物毒性的重要过程,细胞色素P450酶在其中起着关键作用.新烟碱类农药对于哺乳动物毒性较低,但是经过P450酶的转化后,可能会产生毒性增强的代谢产物,提高环境和健康风险.本研究以噻虫嗪(TMX)为例,采用计算模拟的方法研究P450酶催化下TMX的代谢路径和产物,探讨该类污染物N-脱烷基的反应机制.计算结果表明,P450酶代谢TMX有两条不同路径:一条是经过两次O-亚甲基羟基化后通过水桥开环生成毒性减小的噻虫胺(CLO);另一条是通过氢提取/羟基反弹羟基化甲基的过程,然后经水桥转移氢质子发生N-脱甲基反应,生成去甲基噻虫嗪(dm-TMX),据前人实验报道该产物会导致肝肿瘤发生率的增加,具有明显的健康风险.鉴于其他烷基胺类化合物具有类似的代谢机理,进一步通过C—H键解离能(BDEC-H)与氢提取反应的活化能(ΔE*)建立了N-脱烷基化反应活性的预测模型,R2=0.932,平均绝对误差MAE=1.75 kcal·mol-1,模型的稳健性良好,可以快速有效地为该类污染物的代谢活性研究提供... 相似文献
7.
黄孢原毛平革菌固态发酵产漆酶的研究及应用 总被引:3,自引:1,他引:2
对黄孢原毛平革菌(BKMF-1767)利用香蕉皮和玉米棒为发酵底物产胞外漆酶进行了研究.结果表明,当香蕉皮与玉米棒混合比例为1∶2、诱导剂CuSO4为0.4 mmol/L时,能获得最高漆酶酶活12.68 U/g.利用固态发酵所获得的粗漆酶液,进行了降解五氯酚的试验.在没有氧化还原介体时粗漆酶液能降解PCP,粗酶液中加入5 mmol/L氧化还原介体(ABTS)能获得更高的降解率,反应6 h分别为37.8%和97%.将粗漆酶液用(NH4)2SO4盐析纯化,用提纯后漆酶降解PCP,6 h后降解率为81.8%. 相似文献
8.
以赤子爱胜蚓(Eisenia fetida)为受试生物,通过活体与离体实验,研究6:2氟调羧酸(6:2FTCA)在蚯蚓体内的毒理效应和代谢转化机制.结果表明,6:2FTCA对蚯蚓体内丙二醛(MDA)含量和过氧化物酶(POD)活性无显著影响,但能够使过氧化氢酶(CAT)活性提高,使超氧化物歧化酶(SOD)和谷胱甘肽转移酶(GST)活性显著升高,说明6:2FTCA对蚯蚓产生了氧化胁迫效应.6:2FTCA在蚯蚓细胞色素P450(CYP450)和GST酶提取液中的降解动力学均符合一级动力学模型,在CYP450(0.014/h)酶液中的降解速率明显高于GST (0.006/h),其终端全氟羧酸(PFCAs)代谢产物为全氟己酸(PFHxA)、全氟戊酸(PFPeA)和全氟丁酸(PFBA),说明CYP450和GST参与了6:2FTCA在蚯蚓体内的代谢转化,且CYP450贡献大于GST.蚯蚓肠道好氧微生物对6:2FTCA具有显著的降解效果,终端PFCAs降解产物为PFHxA和PFPeA,而肠道厌氧微生物对6:2FTCA无降解作用. 相似文献
9.
蒽降解菌烟曲霉A10的分离及降解性能研究 总被引:3,自引:1,他引:2
从污染环境中筛选出1株蒽降解菌A10,经鉴定为烟曲霉(Aspergillus fumigatus),其对蒽的降解率随时间的延长逐渐升高,在12~84 h,蒽降解率增长速率较快;此后降解率的增加趋于平缓,最终(168 h)能够达到83%左右.当无机盐培养液中蒽初始浓度为10 mg/L,A10投菌量为50 g/L(以湿重计),菌龄为36 h时, 5 d内蒽降解率为79.37%.蒽浓度对菌发挥降解作用有较大影响,浓度为5 mg/L时,降解率最高,达92.17%.培养液初始pH为5.0~7.5时,降解率维持在60%左右;温度为30℃、氧气量为4.30 mg/L时蒽降解效果较好.一定量的营养盐的添加能在一定程度上促进蒽的降解.共代谢底物乳糖的添加,能使蒽的降解率提高37.15%.对蒽降解过程的初步研究表明,菌株A10对蒽的降解是一个胞外吸附/胞内降解的动态变化过程.红外光谱分析显示,在微生物作用下,蒽的结构发生改变,生成了含有1~2个苯环的芳香酸、芳香酮、芳香醛和饱和碳氢化合物等一系列降解产物. 相似文献
10.
Mn2+在黄杆菌FCN2菌株降解芘过程中的作用研究 总被引:1,自引:0,他引:1
利用紫外分光光度法和原子吸收分光光度法研究了Mn2+在菌株FCN2生长细胞、悬浮细胞、粗酶液降解芘时的影响作用.在菌体生长期加入0.1~5 mmol/L的Mn2+,对菌体的生长及生长量无影响,但对芘的降解均有促进作用,以加入0.1mmol/L的Mn2+效果最好,其对芘的平均降解率是对照的1.26倍.此时菌株富集的Mn2+为0.025mmol/L;在用无外加Mn2+培养的菌株FCN2悬浮细胞降解芘时,加入0.5 mmol/L的Mn2+,芘的平均降解率为对照的1.67倍.降解反应发生72h后菌株富集的Mn2+为0.18mmol/L;在酶促降解时加入0.1mmol/LMn2+,平均降解率为对照的1.30倍.结果表明,在不同时期加入的Mn2+对降解芘均有一定的促进作用. 相似文献
11.
黄孢原毛平革菌对6种染料的脱色降解 总被引:45,自引:3,他引:42
在黄孢原毛平革菌与6种染料的液体静培养体系中,不同浓度的染料均发生脱色降解。共培育30 d时,刚果红、直接冻黄G和活性翠蓝KN-G达到92%~99%的脱色率。10,50,100 mg/L活性翠蓝KN-G,50,100 mg/L金莲橙O与天青蓝A,100 mg/L活性艳蓝KN-R的降解率达70%以上;18个样品中60%的降解率超过50%。生物吸附和生物降解是2个重要过程。研究表明,黄孢原毛平革菌对各种染料类群具有广谱有效的脱色降解能力。 相似文献
12.
重金属对白腐菌降解十溴联苯醚的影响 总被引:4,自引:3,他引:1
考察了重金属(Cu、Cd、Pb)对白腐菌生长及其降解十溴联苯醚(BDE-209)的影响及其机制.结果表明,低浓度重金属(≤1 mg.L-1)可促进白腐菌的生长,高浓度则表现为抑制作用,1 mg.L-1时促进作用大小为:Cd>Pb>Cu;白腐菌可高效降解BDE-209,7 d内对BDE-209(1 mg.L-1)降解率可达69.7%;重金属可显著影响白腐菌对BDE-209的降解(P<0.05),低浓度的Cu(≤1 mg.L-1)和Cd(≤0.5 mg.L-1)对BDE-209的降解表现为促进作用,其中Cu为1 mg.L-1时促进作用最明显,降解率为84.4%,而Pb则为抑制作用;高浓度(>1 mg.L-1)的重金属均会抑制BDE-209的降解,抑制作用大小为Cd>Pb>Cu,且随浓度增大抑制作用增强;降解率与生物量变化不完全正相关.白腐菌对BDE-209的降解过程符合一级反应动力学方程,Cu、Cd存在条件下,随着其浓度的增加,降解速率常数k表现为先增加后减少,Cu为1 mg.L-1时k值达到最大,为0.321 2;Pb存在条件下,k值表现为逐渐减小.进一步研究了重金属对白腐菌胞外酶降解BDE-209的影响,并运用SPSS 17.0对胞外酶降解与菌体降解进行距离相关性分析,结果表明,未添加重金属时胞外酶降解与菌体降解差异不大,其降解率分别为63.7%、69.7%;3种重金属存在条件下其相关系数R值均大于0.9,由此推断胞外酶是起降解作用的主要部分,重金属主要通过影响白腐菌胞外酶的方式作用于BDE-209的降解. 相似文献
13.
Functional microorganisms to high concentration phenol containing Cr^6+ and Pb^2+ were cultured and biofilm was formed on polypropylene packings in bioelectro-reactor. It was found that the biodegradation capability of such biofilm to phenol changed with the applied voltage. Under the optimal electric field conditions (voltage of 3.0 V, electric field of strength 17.7 V/m and current density of 1.98 A/m2), biodegradation efficiency of phenol aof concentration of 1200 mg/L increased 33% compared to the instance without applying electric field. However, voltage had inverse effect on biodegradation, as microorganisms were killed under strong electric field. Voltage had little effect on heavy ions elimination. Higher absorption rate of Cr^6+ and Pb^2+ was observed when changing pH fi'om acidic to neutral. The experiment results indicated that, after treatment, 10 L phenol of 2400 mg/L was biodegraded completely within 55 h and concentrations of Cr^6+ and Pb^2+ dropped to less than 1 mg/L within 12 h and 6 h, fi'om initial values of 50 mg/L and 30 mg/L, respectively. 相似文献
14.
揭示白腐真菌(Phanerochaete chrysosporium)在反应器中的形态变化有助于了解白腐真菌反应器难以连续运行问题的本质. 在耦合臭氧单元的反应器对酸性蓝45连续降解的过程中,考察了非固定化和固定化菌丝系统中白腐真菌的形态特性变化. 结果表明,在接种量为1 700 mg/L的非固定化系统中,染菌量为7.1×105 CFU/mL,平均脱色率为19%;但菌丝球形态不稳定,运行8~12 d时出现破裂、菌丝脱落、内容物大量流失,污染微生物的生长加剧. 在固定化系统中,接种量为1 700 mg/L时,染菌量降至8.4×104 CFU/mL,平均脱色率升至22%;接种量为4 300 mg/L时,染菌量降至4.7×104 CFU/mL,平均脱色率达29%. 在固定化菌丝系统中,白腐真菌的形态相对稳定,但21 d后,其稳定性降低,也出现了菌丝脱落现象,这与菌丝球或固定化菌丝的内部菌丝老化和自溶有关,可以考虑通过设计新载体从生物膜的内部和外部同时供给营养物和氧气解决该问题. 相似文献
15.
Response surface methodology (RSM) was employed to evaluate the optimum aerobic biodegradation of dichloromethane (DCM)
in pure culture. The parameters investigated include the initial DCM concentration, glucose as an inducer and hydrogen peroxide
as terminal electron acceptor (TEA). Maximum aerobic biodegradation efficiency was predicted to occur when the initial DCM
concentration was 380 mg/L, glucose 13.72 mg/L, and H2O2 115 mg/L. Under these conditions the aerobic biodegradation rate reached
up to 93.18%, which was significantly higher than that obtained under original conditions. Without addition of glucose, degradation
efficiencies were 6 80% at DCM concentrations < 326 mg/L. When concentrations of DCM were more than 480 mg/L, the addition of
hydrogen peroxide did not help to significantly increase DCM degradation efficiency. When DCM concentrations increased from 240
to 480 mg/L, the overall DCM degradation efficiency decreased from 91% to 60% in the presence of H2O2 for 120 mg/L. 相似文献
16.
从某焦化厂活性污泥中分离筛选出一株能以芴为碳源和能源生长的细菌(命名为W-2),在形态学观察和生理生化试验基础上,利用16S rDNA序列分析及系统发育学分析的方法,鉴定菌株W-2为微嗜酸寡养单胞菌(Stenotrophomonas acidaminiphila).考察了菌株W-2在液体培养基体系内对芴的降解效果,结果表明,该菌株对芴具有良好的降解特性,在初始芴浓度为40mg/L,接种量10%(V/V),pH 7.0,温度30℃条件下,接种该菌11d后,芴的降解效率达到86.0%,说明该菌在芴污染控制方面具有良好的应用前景. 相似文献
17.
Nutrient addition has been proved to be an effective strategy to enhance oil biodegradation in marine shorelines.To determine the optimal range of nutrient concentrations in the bioremediation of oil-polluted beaches,nitrate was added to the simulated shoreline models in the initial concentration of 1,5 and 10 mg/L.Whenever the NO3-N concentration declined to 70% of its original value, additional nutrients were supplemented to maintain a certain range.Results showed adding nutrients increased the oil biodegradation level,the counts of petroleum degrading bacteria(PDB)and heterotrophic bacteria (HB),and the promoted efficiency varied depending on the concentration of nitrate.Oil degradation level in 5 mg/L(NO_3-N)group reached as much as 84.3% accompanied with the consistently highest counts of PDB;while in 1 mg/L group oil removal efficiency was only 35.2%,and the numbers of PDB and HB were relatively low compared to the other groups supplemented with nutrients.Although counts of HB in the 10 mg/L group were remarkable,lower counts of PDB resulted in poorer oil removal efficiency (70.5%) compared to 5 mg/L group.Furthermore,it would need more NO_3-N(0.371 mg)to degrade 1 mg diesel oil in the 10 mg/L group than in the 5 mg/L group(0.197 mg).In conclusion, Nitrate concentration in 5 mg/L is superior to 1 and 10 mg/L in the enhancement of diesel oil biodegradation in simulated shorelines. 相似文献
18.
The phenol and m-cresol biodegradations were studied using the mutant strain CTM 2 obtained by the He-Ne laser irradiation on
wild-type Candida tropicalis. The results showed that C. tropicalis exhibited the increased capacity of phenolic compounds degradation
after laser irradiation. It could degrade 2600 mg/L phenol and 300 mg/L m-cresol by 5% inoculum concentration, respectively. In the
dual-substrate biodegradation system, 0–500 mg/L phenol could accelerate m-cresol biodegradation, and 300 mg/L m-cresol could be
completely utilized within 46 hr at the presence of 350 mg/L phenol. Besides, the maximum biodegradation of m-cresol could reach
350 mg/L with 80 mg/L phenol within 61 hr. Obviously, phenol, as a growth substrate, could promote CTM 2 to degrade m-cresol,
and was always preferentially utilized as carbon source. Comparatively, low-concentration m-cresol could result in a great inhibition
on phenol degradation. In addition, the kinetic behaviors of cell growth and substrate biodegradation were described by kinetic model
proposed in our laboratory. 相似文献
19.
The phenol and m-cresol biodegradations were studied using the mutant strain CTM 2 obtained by the He-Ne laser irradiation on wild-type Candida tropicalis. The results showed that C. tropicalis exhibited the increased capacity of phenolic compounds degradation after laser irradiation. It could degrade 2600 mg/L phenol and 300 mg/L m-cresol by 5% inoculum concentration, respectively. In the dual-substrate biodegradation system, 0-500 mg/L phenol could accelerate m-cresol biodegradation, and 300 mg/L m-cresol could be completely utilized within 46 hr at the presence of 350 mg/L phenol. Besides, the maximum biodegradation of m-cresol could reach 350 mg/L with 80 mg/L phenol within 61 hr. Obviously, phenol, as a growth substrate, could promote CTM 2 to degrade m-cresol, and was always preferentially utilized as carbon source. Comparatively, low-concentration m-cresol could result in a great inhibition on phenol degradation. In addition, the kinetic behaviors of cell growth and substrate biodegradation were described by kinetic model proposed in our laboratory. 相似文献