水稻土Fe(Ⅱ)氧化耦合NO_3~-还原的微生物变化

利用不同驯化条件(Soil、Soil+Fe(Ⅱ)、Soil+NO_3~-和Soil+Fe(Ⅱ)+NO_3~-)对华南水稻土进行中性厌氧条件下的富集培养,探究淹水期水稻土亚铁(Fe(Ⅱ))氧化和硝酸盐(NO_3~-)还原过程,及此过程中微生物群落的变化.结果表明,在Soil+Fe(Ⅱ)处理中,亚铁不能发生自然氧化.只有在Soil+Fe(Ⅱ)+NO_3~-处理中,Fe(Ⅱ)才能被氧化成Fe(Ⅲ);同时,Fe(Ⅱ)的存在减慢了NO_3~-的还原.利用高通量测序技术表征微生物群落组成随培养时间的变化,结果表明,Soil+Fe(Ⅱ)和Soil处理的微生物群落组成没有显著差异.在Soil+NO_3~-处理中,Pseudogulbenkiania、Flavobacterium和Rhodocyclus属成为优势菌群.在Soil+Fe(Ⅱ)+NO_3~-处理中,Zoogloea、Geothrix、Sunxiuqinia和Vulcanibacillus等属成为优势菌群,主要包括硝酸盐还原菌、Fe(Ⅱ)氧化菌和Fe(Ⅲ)还原菌.     

稻秸添加对两种水稻土产甲烷古菌及细菌的影响

稻秸还田对水稻土CH4排放有重要影响.本研究通过微宇宙厌氧培养,研究了两种水稻土[江西(JX)和广东雷州半岛(GD)]在稻秸(RS)添加条件下经相对较长时间的厌氧培养后产甲烷古菌及细菌菌群的响应.结果表明,不同RS添加量对JX水稻土产甲烷古菌群落结构有一定的影响,而对GD水稻土产甲烷古菌群落的影响不大. RS添加量与mcr A基因拷贝数之间存在显著正相关关系,JX水稻土的mcr A基因拷贝数变化对RS添加量的响应更敏感.相同RS添加条件下,JX水稻土mcr A基因拷贝数大于GD水稻土.相同稻秸量添加条件下两种水稻土的产甲烷古菌群落结构也有差异. JX水稻土共检测到的产甲烷古菌有Methanosarcinaceae、Methanocellaceae、Methanomicrobiaceae、Methanobacteriaceae以及未知菌群(494 bp). GD水稻土中仅有3大类产甲烷古菌,分别为Methanobacteriaceae、Methanosarcinaceae和Methanocellaceae.对2%RS处理培养第270 d的细菌菌群进行了测序,发现两种水稻土的细菌菌群明显不同,GD水稻土的细菌多样性高于JX水稻土,而其优势细菌数量(共有Longilinea、Acidobacteria/Gp6、Bellilinea及Thermosporothrix)低于JX水稻土(共有Bacillus、Desulfovirgula、Thermosporothrix、Acidobacteria/Gp1、Acidobacteria/Gp3及Ktedonobacter). RS作为底物促进产甲烷古菌的生长.不同类型的水稻土经相对较长时间的厌氧培养后其产甲烷古菌及细菌菌群结构也不同.     

铁氧化物与电子供体基质交互作用对红壤性水稻土中DDT还原脱氯影响

铁氧化物与电子供体基质交互作用对电子转移及具有脱氯功能的铁还原菌生长有重要影响,进而可能影响土壤中多氯代有机物的还原脱氯降解.本研究采用土壤厌氧培养实验,分析铁氧化物(针铁矿)和电子供体基质(正丁酸和乙醇)及其交互作用对红壤性水稻土中DDT脱氯的影响及其机制.结果表明,由于DDT脱氯降解,DDT及其降解产物与土壤形成结合态残留,厌氧培养6周后,土壤中DDT可提取态残留量仅为初始量的1.29%~2.01%.DDT厌氧脱氯降解的主要产物为DDD.在培养前期,加入正丁酸和乙醇使反应体系的pH降低Eh增加,进而不利于DDT还原脱氯降解.添加针铁矿或者同时添加针铁矿和电子供体基质均使反应体系的pH增加Eh降低,并且增加土壤中二价铁的量,从而促进DDT还原脱氯降解.正丁酸和铁氧化物对DDT还原脱氯无显著交互作用,而乙醇和铁氧化物对DDT还原脱氯具有拮抗作用.本研究结果对于制定DDT污染土壤的高效原位修复技术方案具有重要意义.     

施用堆腐有机肥对水稻土中六氯苯脱氯降解影响

采用水稻盆栽实验,供试土壤为红壤性水稻土和乌栅土,分别设定对照及添加1%和2%堆腐有机肥的处理,研究施用该有机肥对六氯苯(HCB)在种水稻土壤中还原脱氯降解的影响,并分析甲烷生成与HCB脱氯降解的关系.结果表明,18周之后,红壤性水稻土中HCB可提取态残留减少了28.6%～30.1%,乌栅土中HCB可提取态残留减少了47.3%～61.0%;水稻植株吸收的HCB及其降解产物量仅为土壤中HCB初始量的千分之几;HCB发生脱氯降解主要生成五氯苯(PeCB);由于乌栅土的pH和可溶性有机碳含量均高于红壤性水稻土,HCB在乌栅土中的脱氯降解效率较高;在红壤性水稻土中和乌栅土中,施用1%和2%堆腐有机肥分别在第6和第10周后显著抑制PeCB生成,且PeCB生成速率在有机肥的2个添加水平之间均无显著差异;产甲烷菌在脱氯降解中的作用因环境条件而异.     

典型气田土壤铁还原活性与微生物群落关系研究

由微生物驱动的土壤铁还原过程在铁的生物地球化学循环中起到重要作用,该过程还可与土壤重金属的转化及石油烃类有机污染物的降解等过程相偶联.油气田土壤常具有潜在有机污染物风险,本研究以重庆涪陵页岩气田的土壤（潜在烃类有机物污染风险）为对象,测定土壤铁还原活性（Iron Reducing Potential,IRP）,并利用Illumina Miseq测序解析其中的铁还原微生物类群,进而探讨IRP、土壤基本性质及微生物群落之间的关系.结果表明,该区域土壤铁还原菌群的优势菌门为厚壁菌门（Firmicutes）、变形菌门（Proteobacteria）和拟杆菌门（Bacteroidetes）.与低IRP样品相比,高IRP样品中Pseudomonas、norank Peptococcaceae及Lentimicrobium等菌属具有较高的相对丰度.基于各样品OTU （Operational Taxonomic Unit）组成的PCoA （Principal Co-ordinates Analysis）分析表明,高、中及低IRP样品中铁还原菌群落结构差异显著（R²=0.25,p<0.01）,且一些分别属于Acetoanaerobium、Proteiniphilum、Petrimonas、Tessaracoccus及Exiguobacterium菌属中的OTUs在高IRP样品中显著上调.结构方程模型表明,铁还原微生物的群落结构是直接决定土壤IRP的主要因子,土壤氨氮及有效磷均可通过影响微生物群落结构来间接影响IRP,且氨氮还可通过直接影响有效磷来间接影响土壤IRP.本研究揭示了影响典型页岩气田土壤铁还原活性的关键因子及微生物机制,为进一步深入研究铁还原条件下土壤有机污染物去除的微生物机制打下基础.     

五氯苯酚对污泥性能和功能基因表达水平的影响

氯酚废水是一类广泛存在于环境的典型工业废水,具有显著的生态毒性,为探讨废水中氯酚类化合物对污泥性能和功能基因表达水平的影响,采用HRT（水力停留时间）为8 h、SBR（间歇曝气的序批式生物反应器）处理进水浓度为2 mg/L的PCP（五氯苯酚）废水,并与处理不含PCP的废水作对比分析,探讨PCP对污染物去除和微生物菌群的影响,并分析PCP诱导下污泥中Pseudomonas功能基因的表达水平.结果表明:①1~90 d,进水浓度为2 mg/L的PCP严重抑制污泥活性,出水ρ（COD_Cr）超过100 mg/L,PCP降解去除缓慢,而对照组出水ρ（COD_Cr）在31.6 mg/L左右波动.90 d后,降解PCP的优势菌群富集,水相、泥相PCP被降解去除,但PCP的毒性作用使其出水ρ（COD_Cr）仍高于对照组.②经PCP长期驯化污泥富集的优势菌属为Chondromyces、Ignavibacterium、Thauera、Pseudoxanthomonas、Bosea、Achromobacter、Comamonas和Salimesophilobacter,均归属于变形菌门和厚壁菌门,在降解氯酚类污染物方面起着重要作用.③当处理PCP的SBR处于稳定运行阶段时,SBR运行周期末污泥中降解PCP的菌属Pseudomonas调控ATP水解酶（ATPase）、过氧化氢酶（CAT）和细胞色素p450（CYP450）的功能基因表达被激活,而调控超氧化物歧化酶（SODb）、氨单加氧酶（AM）、脱氯水解酶（HDLH）和甘油三磷酸脱氢酶（GAPDH）的功能基因表达被抑制,即活性污泥中微生物调控不同基因的表达受进水PCP的抑制或激活.研究显示:进水PCP诱导SBR富集的优势菌属可实现废水中PCP的去除,起到削减废水毒性的作用;通过分析不同优势菌属的相关功能基因表达,可加强对不同微生物降解污染物机理的认识.      

稻田NO_3~-还原耦合As(Ⅲ)氧化过程及微生物群落特征

以华南稻田土壤为研究对象通过构建微宇宙体系,研究了淹水稻田自养硝酸盐还原耦合As(Ⅲ)氧化过程及其微生物群落结构组成.结果表明,NO_3~-的添加促进了稻田土壤中As(Ⅲ)的氧化,在未添加NO_3~-的处理(Soil+As(Ⅲ))以及灭菌处理(Sterilizedsoil+As(Ⅲ)+NO_3~-)中As(Ⅲ)未发生明显的氧化;在Soil+As(Ⅲ)+NO_3~-处理中,NO_3~-有少量被还原,而在Soil+NO_3~-处理中,NO_3~-没有被还原.通过16S rRNA高通量分析在NO_3~-还原耦合As(Ⅲ)氧化体系中微生物群落结构特征,在Soil+As(Ⅲ)+NO_3~-处理中shannon指数相对较低为8.19,土壤微生物群落多样性降低,其中在门水平上主要优势菌群为变形菌门Proteobacteria(33%)、绿弯菌门Chloroflexi(11%)、浮霉菌门Planctomycetes(12%);在属水平上主要的优势菌属为Gemmatimonas(7.4%)以及少量的Singulisphaera、Thermomonas、Bacillus.NO_3~-的添加能够促进稻田土壤中自养As(Ⅲ)氧化,并且影响着稻田土壤中微生物群落组成.     

固定化好氧菌和厌氧颗粒污泥在不同供氧条件下降解氯酚的研究

将厌氧颗粒污泥和4种氯酚的高效降解菌种固定化后,通过批处理实验较系统地研究了其在有限供氧、完全厌氧及好氧条件下在初始浓度为28和87μmol·L-1五氯苯酚(PCP)的降解过程.结果表明,完全厌氧过程尽管能有效降解低初始浓度PCP,但在高初始浓度下由于厌氧微生物本身缺乏吸收、同化其代谢产物单氯酚(MCP)和二氯酚(DCP)的能力,而导致了有毒代谢产物的积累,阻碍了其完全降解;在有限供氧条件下,通过厌氧颗粒中的厌氧菌群与好氧或兼性菌的协同作用,借助于好氧或兼性菌消除五氯苯酚厌氧过程中产生的抑制性的低氯酚等中间产物,从而使其较完全降解;与完全厌氧过程相比,混合固定化颗粒污泥在有限供氧系统具有较低的残留TOC值.厌氧好氧微生物菌群通过固定化在微环境中有效的结合在有限供氧条件下能完全彻底降解高氯代芳香化合物.     

氯代烯烃胁迫下菌群SWA1的降解活性及群落结构

以填埋场覆盖土筛选的可高效降解三氯乙烯(TCE)的混合菌群SWA1为研究对象,考察了其对高浓度氯代烯烃的耐受性及微生物群落变化.SWA1对反-1,2-二氯乙烯(t-1,2-DCE),TCE和四氯乙烯(PCE)的最高耐受浓度分别可达580,250,500mg/L,远高于已报道菌株.生物降解研究结果表明SWA1可有效去除氯代烯烃,菌群生长到稳定期,对t-1,2-DCE的去除率高于90%.高通量测序结果和相关性分析显示不同氯代烯烃驯化后SWA1群落结构存在显著性差异,t-1,2-DCE共代谢生物降解中参与甲烷氧化和氯代烃降解的优势菌属分别为Methylophilus(相对丰度为17.4%~26.6%)和Methylomonas(相对丰度为31.7%~62.2%);TCE共代谢降解中参与甲烷氧化和氯代烃降解的优势菌属分别为Methylophilus(相对丰度为26.9%~46.3%)和Methylocystaceae(相对丰度为1.7%~33.4%).群体感应分析表明微生物间互利共生关系促进了SWA1的生物氧化.     

氯酚污染土壤的生物强化修复及其微生物种群动态变化的分子生物学监测

在氯酚污染的土壤中接种氯酚降解菌,研究了受污染土壤的生物强化修复.利用传统的微生物计数方法和现代分子生物学手段,研究了生物强化修复过程中微生物种群的动态变化情况.在受氯酚污染的土壤样品中,以氯酚为唯一碳源和能源,分离出了多株对氯酚具有较高降解能力的微生物,利用16S rDNA序列分析方法对部分微生物进行了种属鉴定.土壤中存在的土著的氯酚降解菌可以对低含量的氯酚(100mg·g-1)进行降解;但是当土壤中氯酚含量较高(500 mg·g-1)时,土著微生物的降解能力受到限制,这可能是高浓度的氯酚对土著的氯酚降解菌会产生毒性作用.接种外来微生物后,土壤中可以培养的氯酚降解菌的总数从开始的106CFU·g-1增加到108CFU·g-1,并且,在氯酚含量为100 mg·g-1的土壤样品中,微生物数目的增加比在氯酚含量为500 mg·g-1土壤样品中更快.这表明接种的外来微生物可以在土壤中很好地生长繁殖,有效地促进土壤中氯酚的生物降解.接种外来微生物可以减轻土壤中氯酚对土著微生物初期产生的不利影响.土壤中的氯酚可能会改变微生物种群结构.DGGE分析结果表明,在未受氯酚污染和受氯酚污染的土壤样品中,存在一些共同的DNA谱带,但谱带强度有明显的差异.在受污染的土壤中接种外来微生物进行生物强化,可以促进污染物的生物降解过程,是生物修复过程中的一种重要手段,有着广泛的应用前景,将在我国受污染环境的生物修复中发挥重要作用.     

Toxic effects of acetochlor, methamidophos and their combination on nifH gene in soil

Toxic effects of two agrochemicals on nifH gene in agricultural black soil were investigated using denaturing gradient gel electrophoresis （DGGE） and sequencing approaches in a microcosm experiment. Changes of soil nifH gene diversity and composition were examined following the application of acetochlor, methamidophos and their combination. Acetochlor reduced the nifH gene diversity （both in gene richness and diversity index values） and caused changes in the nifH gene composition. The effects of acetochlor on nifH gene were strengthened as the concentration of acetochlor increased. Cluster analysis of DGGE banding patterns showed that nifH gene composition which had been affected by low concentration of acetochlor （50 mg/kg） recovered firstly. Methamidophos reduced nifH gene richness that except at 4 weeks. The medium concentration of methamidophos （150 mg/kg） caused the most apparent changes in nifH gene diversity at the first week while the high concentration of methamidophos （250 mg/kg） produced prominent effects on nifH gene diversity in the following weeks. Cluster analysis showed that minimal changes of nifH gene composition were found at 1 week and maximal changes at 4 weeks. Toxic effects of acetochlor and methamidophos combination on nifH gene were also apparent. Different nifH genes （bands） responded differently to the impact of agrochemicals： four individual bands were eliminated by the application of the agrochemicals, five bands became predominant by the stimulation of the agrochemicals, and four bands showed strong resistance to the influence of the agrochemicals. Fifteen prominent bands were partially sequenced, yielding 15 different nifH sequences, which were used for phylogenetic reconstructions. All sequences were affiliated with the alpha- and beta-proteobacteria, showing higher similarity to eight different diazotrophic genera.     

Arsenic uptake by arbuscular mycorrhizal maize （Zea mays L.） grown in an arsenic-contaminated soil with added phosphorus

The effects of arbuscular mycorrhizal (AM) fungus (Glomus mosseae) and phosphorus (P) addition (100 mg/kg soil) on arsenic (As) uptake by maize plants (Zea mays L.) from an As-contaminated soil were examined in a glasshouse experiment.Non-mycorrhizal and zero-P addition controls were included.Plant biomass and concentrations and uptake of As,P,and other nutrients,AM colonization,root lengths,and hyphal length densities were determined.The results indicated that addition of P significantly inhibited root colonization and development of extraradical mycelium.Root length and dry weight both increased markedly with mycorrhizal colonization under the zero-P treatments,but shoot and root biomass of AM plants was depressed by P application.AM fungal inoculation decreased shoot As concentrations when no P was added,and shoot and root As concentrations of AM plants increased 2.6 and 1.4 times with P addition,respectively.Shoot and root uptake of P,Mn,Cu,and Zn increased,but shoot Fe uptake decreased by 44.6%,with inoculation, when P was added.P addition reduced shoot P,Fe,Mn,Cu,and Zn uptake of AM plants,but increased root Fe and Mn uptake of the nonmycorrhizal ones.AM colonization therefore appeared to enhance plant tolerance to As in low P soil,and have some potential for the phytostabilization of As-contaminated soil,however,P application may introduce additional environmental risk by increasing soil As mobility.     

Degradation of metabolites accumulated of benzo[a]pyrene by coupling Penicillium Chrysogenum with KMnO4

Several main metabolites of benzo[a]pyrene （BaP） formed by Penicillium chrysogenum, Benzo[a]pyrene-1,6-quinone （BP 1,6- quinone）, trans-7,8-dihydroxy-7,8-dihydrobenzo[a]pyrene （BP 7,8-diol）, 3-hydroxybenzo[a]pyrene （3-OHBP）, were identified by high-performance liquid chromatography （HPLC）. The three metabolites were liable to be accumulated and were hardly further metabolized because of their toxicity to microorganisms. However, their further degradation was essential for the complete degradation of BaP. To enhance their degradation, two methods, degradation by coupling Penicillium chrysogenum with KMnO4 and degradation only by Penicillium chrysogenum, were compared; Meanwhile, the parameters of degradation in the superior method were optimized. The results showed that （1） the method of coupling Penicillium chrysogenum with KMnO4 was better and was the first method to be used in the degradation of BaP and its metabolites; （2） the metabolite, BP 1,6-quinone was the most liable to be accumulated in pure cultures; （3） the effect of degradation was the best when the concentration of KMnO4 in the cultures was 0.01% （w/v）, concentration of the three compounds was 5 mg/L and pH was 6.2. Based on the experimental results, a novel concept with regard to the bioremediation of BaP-contaminated environment was discussed, considering the influence on environmental toxicity of the accumulated metabolites.     

Impact of atrazine and nitrogen fertilizers on the sorption of chlorotoluron in soil and model sorbents

Sorption of chlorotoluron in ammonium sulfate, urea and atrazine multi-solutes system was investigated by batch experiments. The results showed application of nitrogen fertilizers to the soil could affect the behavior of chlorotoluron. At the same concentration of N, sorption of chlorotoluron decreased as the concentration of atrazine increased on the day 0 and 6 in soil, respectively. The sorption of chlorotoluron increased from 0 to 6 d when soils were preincubated with deionized water, ammonium sulfate and urea solution for 6 d. That indicated incubation time was one of the most important factors for the sorption of chlorotoluron in nitrogen fertilizers treatments. The individual sorption isotherms of chlorotoluron in rubbery polymer and silica were strictly linear in single solute system, but there were competition sorption between pesticides or between pesticides and nitrogen fertilizers. That indicated the sorption taken place by concurrent solid-phase dissolution mechanism and sorption on the interface of water-organic matter or water-mineral matter.     

Distribution and ecological effect of mercury in Laogang landfill, Shanghai, China

Laogang landfill near Shanghai is the largest landfill in China, and receives about 10000 t of daily garbage per day, Samples of topsoil and plants were analyzed to evaluate mercury pollution from the landfill. For topsoil samples, there were significant correlations among total mercury （HgT）, combinative mercury （Hgc） and gaseous mercury （HgG）, and content of total organic carbon （TOC）, but, no significantly relationship was found between Hg content and filling time. Hg content changes in vertical profiles with time showed that the average Hgv of profiles 1992, 1996, and 2000 was similar, but their average HgG was quite different. HgT was significantly correlated with Hgc in profile 1992 and 2000, and Hgv was significantly correlated with Hg6 in profile 1996. HgG/Hgv ratio in profile samples decreased in the order of （HgG,/HgT）1992〉（HgG/HgT）1996〉〉（HgG/HgT）2000. A simple outline of Hg release in landfill could be drawn： with increasing of filling time, degradation undergoes different biodegradation, accordingly, gaseous mercury goes through small, more, and small proportion to total mercury. Distribution of Hg in plants was inhomogeneous, following the order of leaf〉root〉stem. The highest value of leaf may be associated with higher atmospheric Hg from landfill. Ligneous plants （e.g. Phyllostachys glanca, Prunus salicina and Ligustrum lucidum） are capable of enriching more Hg than herbaceous plants.     

EDTA-enhanced phytoremediation of lead contaminated soil by Bidens maximowicziana

Phytoremediation is a potential cleanup technology for the removal of heavy metals from contaminated soils.Bidens maximowicziana is a new Pb hyperaccumulator,which not only has remarkable tolerance to Pb but also extraordinary accumulation capacity for Pb.The maximum Pb concentration was 1509.3 mg/kg in roots and 2164.7 mg/kg in overground tissues.The Pb distribution order in the B. maximowicziana was:leaf>stem>root.The effect of amendments on phytoremediation was also studied.The mobility of soil Pb and the Pb concentrations in plants were both increased by EDTA application.Compared with CK(control check),EDTA application promoted translocation of Pb to overground parts of the plant.The Pb concentrations in overground parts of plants was increased from 24.23-680.56 mg/kg to 29.07-1905.57 mg/kg.This research demonstrated that B.maximowicziana appeared to be suitable for phytoremediation of Pb contaminated soil,especially,combination with EDTA.     

Decomposition of alachlor by ozonation and its mechanism

Decomposition and corresponding mechanism of alachlor, an endocrine disruptor in water by ozonation were investigated. Results showed that alachlor could not be completely mineralized by ozone alone. Many intermediates and final products were formed during the process, including aromatic compounds, aliphatic carboxylic acids, and inorganic ions. In evoluting these products, some of them with weak polarity were qualitatively identified by GC-MS. The information of inorganic ions suggested that the dechlorination was the first and the fastest step in the ozonation of alachlor.     

Enzymatic oxidation of aqueous pentachlorophenol

The influence of the nonionic surfactant Tween 80 on pentachlorophenol （PCP） oxidation catalyzed by horseradish peroxidase was studied. The surfactant was tested at concentrations below and above its critical micelle concentration （CMC）. Enhancement of PCP removal was observed at sub-CMCs. The presence of Tween 80 in the reaction mixture reduced enzyme inactivation which occurred through a combination of free radical attack and sorption by precipitated products. A simple first-order model was able to simulate time profiles for enzyme inactivation in the presence or absence of Tween 80. At supra-CMCs, the surfactant caused noticeable reductions in PCP removal, presumably through micelle partitioning of PCP which precluded the hydrophobic PCP molecule from interacting with the enzyme.     

Potential of plant polyphenol oxidases in the decolorization and removal of textile and non-textile dyes

In this study an effort has been made to use plant polyphenol oxidases; potato （Solanum tuberosum） and brinjal （Solanum melongena）, for the treatment of various important dyes used in textile and other industries. The ammonium sulphate fractionated enzyme preparations were used to treat a number of dyes under various experimental conditions. Majority of the treated dyes were maximally decolorized at pH 3.0. Some of the dyes were quickly decolorized whereas others were marginally decolorized. The initial first hour was sufficient for the maximum decolorization of dyes. The rate of decolorization was quite slow on long treatment of dyes. Enhancement in the dye decolorization was noticed on increasing the concentration of enzymes. The complex mixtures of dyes were treated with both preparations of polyphenol oxidases in the buffers of varying pH values. Potato polyphenol oxidase was significantly more effective in decolorizing the dyes to higher extent as compared to the enzyme obtained from brinjal polyphenol oxidase. Decolorization of dyes and their mixtures, followed by the formation of an insoluble precipitate, which could be easily removed simply by centrifugation.     

Removal of heavy metals from sewage sludge by low costing chemical method and recycling in agriculture

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