微生物氧化As(III)和Sb(III)的研究进展

砷(Arsenic,As)和锑(Antimony,Sb)属于同族元素,具有相似的化学性质,是公认的有毒类金属(metalloid),广泛存在于自然界中。随着人类的发展,环境中砷和锑的污染日益严重,类金属污染环境的修复已经刻不容缓。现已表明,自然界中的微生物在砷和锑的生物地球化学循环中发挥着重要的作用,尤其是微生物的氧化作用,可以将毒性较强的亚砷酸盐[Arsenite,As(III)]和亚锑酸盐[Antimonite,Sb(III)]氧化为毒性较低的砷酸盐[Arsenate,As(V)]和锑酸盐[Antimonate,Sb(V)],被认为是一种潜在的类金属污染环境修复方法。本文就国内外对As(III)氧化菌和Sb(III)氧化菌的多样性、As(III)和Sb(III)微生物氧化调控机制和应用的研究进展进行总结,旨在为深入了解和探索微生物介导的砷和锑生物地球化学循环及污染环境的微生物修复提供参考。     

抗砷性微生物及其抗砷分子机制研究进展

砷(Arsenic, As)是一种剧毒类金属(Metalloid), 在自然环境中主要以三价亚砷酸盐[Arsenite, AsO2-, As(III)]和五价砷酸盐[Arsenate, AsO43-, As(V)]的无机形式广泛存在。许多微生物在含砷环境的长期适应过程中, 进化了多种不同的砷解毒抗性机制。目前研究发现主要存在4种类型的砷抗性机理, 包括: As(III)氧化, 细胞质As(V)还原, 呼吸性As(V)还原, As(III)甲基化, 这些机制赋予微生物砷抗性并在砷的转化和地球化学循环中起着极     

微生物氧化As(Ⅲ)和Sb(Ⅲ)的研究进展

砷(Arsenic,As)和锑(Antimony,Sb)属于同族元素,具有相似的化学性质,是公认的有毒类金属(Metalloid),广泛存在于自然界中。随着人类的发展,环境中砷和锑的污染日益严重,类金属污染环境的修复已经刻不容缓。现已表明,自然界中的微生物在砷和锑的生物地球化学循环中发挥着重要的作用,尤其是微生物的氧化作用,可以将毒性较强的亚砷酸盐[Arsenite,As(Ⅲ)]和亚锑酸盐[Antimonite,Sb(Ⅲ)]氧化为毒性较低的砷酸盐[Arsenate,As(V)]和锑酸盐[Antimonate,Sb(V)],被认为是一种潜在的类金属污染环境修复方法。本文就国内外对As(Ⅲ)氧化菌和Sb(Ⅲ)氧化菌的多样性、As(Ⅲ)和Sb(Ⅲ)微生物氧化调控机制和应用的研究进展进行总结,旨在为深入了解和探索微生物介导的砷和锑生物地球化学循环及污染环境的微生物修复提供参考。     

“吃”砒霜的细菌--解析微生物的砷代谢

研究发现一些微生物可以利用剧毒的类金属砷(As)为自身生长获取能量甚至用砷代替磷维持生长。本文综合分析了近期的研究进展,从以下6方面解析微生物多重的砷代谢产能机制:(1)化能无机自养As(Ⅲ)氧化供能;(2)有机异养型As(Ⅲ)氧化供能;(3)呼吸性As(Ⅴ)还原供能;(4)As(Ⅲ)氧化偶联的光合作用;(5)As(Ⅲ)氧化、As(Ⅴ)、还原As(Ⅲ)氧化偶联的光合作用之间的关联;(6)As(Ⅴ)代替磷维持细菌生长。阐明微生物利用砷的机理在生命起源、生命多样性、进化、地球化学循环及污染治理等方面都具有重要价值。     

水体硝化体系中砷的解毒机制探讨

硝化是目前废水生物脱氮中应用最为广泛的工艺之一,其功能菌为化能自养型细菌,生长缓慢,对重金属十分敏感。砷是一种剧毒的类金属元素,主要以无机形式的亚砷酸盐[AsO₂^-,As（Ⅲ）]和砷酸盐[AsO₄^3-,As（Ⅴ）]存在,尤以As（Ⅲ）毒性最强。但研究发现,在硝化体系中,高浓度As（Ⅲ）(约400mg/L)未对硝化功能微生物产生明显毒性。深入比较发现,As（Ⅲ）的生物氧化与硝化过程具有一定的关联性。化能自养型As（Ⅲ）氧化菌不仅可在有氧条件下将As（Ⅲ）氧化,还可在缺氧条件下以NO₂^–或NO₃^–为电子受体氧化As（Ⅲ）。而硝化细菌也是典型的化能自养菌,且硝化体系内存在氧气及硝化产物NO₂^–、NO₃^–等电子受体,理论上均可接受电子实现As（Ⅲ）的氧化。本文结合硝化反应特性,综述了As（Ⅲ）在硝化体系下的解毒机制,主要为胞外聚合物的...     

紫色非硫细菌的砷代谢机制

[目的]系统阐述紫色非硫细菌(PNSB)砷代谢机制和砷代谢基因簇的进化关系.[方法]通过生物信息学方法分析了PNSB砷代谢基因簇的分布、组成、排布方式.采用UV-Vis和HPLC-ICP-MS方法,研究了3个PNSB种类对砷的抗性、砷形态及价态的转化、砷在细胞中的积累和分布以及磷酸盐对As细胞毒性的影响.[结果]砷基因簇分析表明:已公布全基因组序列的17个PNSB菌株基因组中均含有以ars operon为核心的砷代谢基因簇,由1-4个操纵子组成,主要含有与细胞质砷还原和砷甲基化代谢相关的基因,但基因的组成和排列方式因种和菌株而异,尤其是arsM和两类进化来源不同的arsC.实验结果表明:光照厌氧条件下,3个PNSB种类对As(V)和As(Ⅲ)均具有抗性,As(V)和As(Ⅲ)均能进入细胞 ;在胞内As(V)能够还原为As(Ⅲ)并被排出胞外,但不能将As(Ⅲ)氧化为As(V),也未检测到甲基砷化物 ;磷酸盐浓度升高,能够抑制As(V)进入细胞,降低As(V)对细胞的毒性,而不能抑制As(Ⅲ)进入细胞.[结论]PNSB砷代谢机制主体为细胞质As(V)还原,也还有砷甲基化途径.通过对砷代谢基因簇结构多样性特点和进化方式分析,提出了与Rosen不同的ars operon进化途径.这对深入开展PNSB砷代谢和基因之间的相互作用研究奠定基础.     

铁氧化菌耐砷机制及其砷污染修复应用的研究进展

砷污染作为全球性环境问题已经引起了人们的高度重视。无机砷化合物可与铁氢氧化物络合通过共沉淀作用去除。因此,利用具有砷耐性的铁氧化菌氧化环境中的铁元素去除砷化合物具有潜在的应用前景。目前已有利用铁氧化菌去除环境中砷污染物的报道。用于砷污染修复的铁氧化菌必须有一定的砷耐性才能在含砷环境中行使功能。微生物是否具有砷耐性往往取决于基因,并且不同的菌株具有不同的生理特征,适宜不同砷污染环境的修复。本文通过对8株代表性的铁氧化菌砷耐性基因的总结,阐述其耐砷机制、研究概况及应用前景,以期为铁氧化菌用于除砷新技术的开发提供参考。     

节杆菌FX8的分离筛选及其生物成矿除砷

【背景】砷（arsenic,As）是一种剧毒的类金属,水体砷污染问题日益突出,严重威胁人类健康,开发高效除砷方法迫在眉睫。【目的】吸附法是目前除砷应用最多的方法之一,对从铁矿表层土壤分离得到的一株铁氧化菌FX8进行研究,以期通过其氧化Fe （II）生成的铁矿物作为吸附剂而去除砷。【方法】通过形态学特征、生理生化特性、全基因组测序分析对菌株进行鉴定,采用邻菲罗啉分光光度法测定总Fe和Fe （II）,利用X射线衍射（X-ray diffraction,XRD）、X射线光电子能谱（X-ray photoelectron spectroscopy,XPS）和能量色散谱（energy dispersive spectrometer,EDS）对铁氧化物沉淀进行分析,采用高压液相色谱-氢化物发生-原子荧光光谱测定总As。【结果】菌株FX8为革兰氏阳性、好氧,其菌落为圆形、乳白色,扫描电镜（scanning electron microscope,SEM）镜检细胞为杆状,大小为（0.5-2.5）μm×（0.13-0.25）μm,可归为节杆菌属（Arthrobacter）。菌株FX8能够氧化Fe （II）并生成铁氧化物沉淀,该沉淀为一种无定形的Fe （III）矿物,其结晶性差且含有大量生物杂质,并且通过产生胞外酶氧化Fe （II）。菌株FX8在28℃、150 r/min条件下,在加As （III）和As （V）体系中,48 h内总Fe的去除率均为100%,而对应的总As去除率分别为99.54%和99.86%;在As （III）和As （V）体系中加入菌株FX8的胞外粗酶液,2 h内总Fe的去除率均为100%,相应的总As去除率为99.45%和100%。【结论】菌株FX8是一株铁氧化菌,利用其胞外粗酶液生物矿化铁除砷的效果优于菌株-砷共培养,本研究可为水体砷污染的高效生物修复提供新的生物材料及理论参考。     

微生物耐砷机理及其在砷地球化学循环中的作用北大核心CSCD

砷是一种无处不在的有毒类金属,其强致癌性引起了人类的广泛关注。在自然环境中,砷的转化存在物理化学过程和生物过程,其中微生物介导的砷转化是环境砷行为的主要影响因素。微生物的耐砷特性与砷吸收、氧化还原、甲基化、区隔化和外排等过程密切相关。砷在微生物体内的转运转化主要与砷解毒有关,但某些微生物可利用氧化还原过程产生的能量以维持其生长需求。本文综述了微生物介导的砷吸收、转化、区隔化和外排机制,这对阐明砷的地球化学循环过程及指导砷污染土壤和水体修复、阻控农作物砷吸收等方面具有重要意义。     

4种蚯蚓肠道微生物对砷毒性的响应差异研究

蚯蚓肠道是微生物多样性的一个潜在存储库。砷对蚯蚓肠道微生物群落的影响已被证实,但砷在不同蚯蚓肠道菌群中生物转化的差异仍不清楚。为了进一步阐述土壤中广泛存在的低浓度砷(浓度为5,15,25 mg/kg)对不同种类蚯蚓肠道微生物影响的差异,将4种典型蚯蚓暴露于砷污染土壤后,测定其肠道微生物组成变化,并分析砷对不同蚯蚓肠道内砷富集、形态和砷生物转化基因的影响。结果显示,所有蚯蚓组织内均存在明显的砷富集,其富集系数由高到低依次为:安德爱胜蚓(1.93)>加州腔蚓(0.80)>通俗腔蚓(0.78)>湖北远盲蚓(0.52),蚯蚓组织和肠道内砷形态主要以无机砷为主,其中As(III)含量比例> 80%,部分蚯蚓组织内还发现少量有机砷。4种蚯蚓肠道微生物群落在门水平上主要以变形菌、厚壁菌和放线菌为主,并与周围土壤细菌群落组成存在显著差异。同时,在土壤和肠道内共检测到17个砷转化基因,其中蚯蚓肠道内As(V)还原和砷转运相关基因相对丰度较高,而砷(去)甲基化基因丰度较低。此外,低浓度砷污染对蚯蚓生长无显著影响,却能引起蚯蚓肠道微生物群落的紊乱。蚯蚓种类和砷污染是引起蚯蚓肠道微生物...     

砷暴露诱导人肝细胞氧化应激过程中NADPH氧化酶作用机制

目的：探讨砷暴露诱导细胞氧化应激的分子机制。方法：采用人正常肝细胞进行亚砷酸钠和砷酸钠的暴露处理,并设相应对照组,采用SOD模拟物MnTMPyP和还原型谷胱甘肽（reducedglutathione,GSH）预处理,检测细胞超氧阴离子（02。）和细胞整体ROS的水平。WestemBlot方法检测细胞氧化／抗氧化重要酶微粒体谷胱甘肽硫转移酶（microsomalglutathioneS-transferase-l,Mgst．1）、半胱氨酸双加氧酶l（cysteinedioxygenasel,Cd01）和NADPH氧化酶的催化亚基NOX4的表达。针对NADPH氧化酶,采用特异性抑制剂（diphenyleneiodoniumchloride,DPI）进行预处理,观察对砷暴露引起的细胞ROS水平及细胞凋亡的影响。结果：砷暴露能够显著诱导细胞超氧阴离子的产生,提高细胞整体ROS水平,其中三价砷（亚砷酸钠,A矿）诱导氧化应激作用显著强于五价砷（砷酸钠,As5＋）。亚砷酸钠能够显著提高NOX4的表达。针对NADPH氧化酶的抑制剂DPI能够显著抑制砷暴露引起的细胞ROS水平升高以及细胞凋亡的增加。结论：NADPH氧化酶是砷暴露诱导人肝细胞的作用靶点,砷能够通过NADPH氧化酶产生大量超氧阴离子,提高ROS水平,造成氧化应激,诱导人正常肝细胞凋亡。     

Arsenite Oxidation in Ancylobacter dichloromethanicus As3-1b Strain: Detection of Genes Involved in Arsenite Oxidation and CO2 Fixation

The aim of this study was to characterize a facultative chemolithotrophic arsenite-oxidizing bacterium by evaluating the growth and the rate of arsenite oxidation and to investigate the genetic determinants for arsenic resistance and CO(2) fixation. The strain under study, Ancylobacter dichloromethanicus As3-1b, in a minimal medium containing 3 mM of arsenite as electron donor and 6 mM of CO(2)-bicarbonate as the C source, has a doubling time (t(d)) of 8.1 h. Growth and arsenite oxidation were significantly enhanced by the presence of 0.01 % yeast extract, decreasing the t(d) to 4.3 h. The strain carried arsenite oxidase (aioA) gene highly similar to those of previously reported arsenite-oxidizing Alpha-proteobacteria. The RuBisCO Type-I (cbbL) gene was amplified and sequenced too, underscoring the ability of As3-1b to carry out autotrophic As(III) oxidation. The results suggest that A. dichloromethanicus As3-1b can be a good candidate for the oxidation of arsenite in polluted waters or groundwaters.     

Arsenic toxicity is not due to a direct effect on the oxidation of reduced inorganic sulfur compounds by Thiobacillus caldus

Abstract Thiobacillus caldus is a moderately thermophilic acidophile which has been implicated in the biooxidation of arsenic containing mineral Sulfides. The toxic effects of arsenic on this bacterium are presented here. Addition of arsenite to a growing culture of T. caldus caused a transient increase in the optical density of the culture while causing a simultaneous decrease in cell viability. The increase in optical density was shown to be due to the formation of extracellular sulfur. The oxidation rates of tetrathionate and thiosulfate were decreased by increasing concentrations of arsenite, while in a culture induced to arsenic resistance the rates were not as adversely effected. Sulfur oxidation was also inhibited to the same extent as tetrathionate oxidation, with the oxidation of solid sulfur being slightly more effected than the oxidation of sulfur dissolved in acetone. Thus, bactericidal arsenite causes a transient formation of extracellular sulfur in the culture supernatant of T. caldus yet the toxicity of arsenite is not due to direct inhibitory effects on reduced inorganic sulfur compound oxidation by these bacteria.     

Biological characterization of Bacillus flexus strain SSAI1 transforming highly toxic arsenite to less toxic arsenate mediated by periplasmic arsenite oxidase enzyme encoded by aioAB genes

Bacillus flexus strain SSAI1 isolated from agro-industry waste, Tuem, Goa, India displayed high arsenite resistance as minimal inhibitory concentration was 25 mM in mineral salts medium. This bacterial strain exposed to 10 mM arsenite demonstrated rapid arsenite oxidation and internalization of 7 mM arsenate within 24 h. The Fourier transformed infrared (FTIR) spectroscopy of cells exposed to arsenite revealed important functional groups on the cell surface interacting with arsenite. Furthermore, scanning electron microscopy combined with electron dispersive X-ray spectroscopy (SEM-EDAX) of cells exposed to arsenite revealed clumping of cells with no surface adsorption of arsenite. Transmission electron microscopy coupled with electron dispersive X-ray spectroscopic (TEM-EDAX) analysis of arsenite exposed cells clearly demonstrated ultra-structural changes and intracellular accumulation of arsenic. Whole-genome sequence analysis of this bacterial strain interestingly revealed the presence of large number of metal(loid) resistance genes, including aioAB genes encoding arsenite oxidase responsible for the oxidation of highly toxic arsenite to less toxic arsenate. Enzyme assay further confirmed that arsenite oxidase is a periplasmic enzyme. The genome of strain SSAI1 also carried glpF, aioS and aioE genes conferring resistance to arsenite. Therefore, multi-metal(loid) resistant arsenite oxidizing Bacillus flexus strain SSAI1 has potential to bioremediate arsenite contaminated environmental sites and is the first report of its kind.

     

胶原蛋白多肽-铬（Ⅲ）螯合物对糖尿病小鼠免疫力的影响

目的研究胶原蛋白多肽-铬（Ⅲ）（CPCC）螯合物对由四氧嘧啶诱发糖尿病小鼠的免疫力的影响。方法通过腹腔注射四氧嘧啶造小鼠糖尿病模型,观察胶原蛋白多肽-铬（Ⅲ）螯合物对小鼠血糖、脾指数、胸腺指数、脾细胞增殖能力、NK细胞杀伤活性、CD40、CD40L的表达等指标的影响。结果胶原蛋白多肽-铬（Ⅲ）螫合物可以有效预防小鼠血糖升高,对脾指数、胸腺指数有一定的恢复作用,脾细胞增殖能力明显增强,NK细胞的杀伤活性被提高,CD40、CD40L的阳性表达率增加。结论胶原蛋白多肽-铬（Ⅲ）能活化免疫细胞,恢复和改善小鼠机体的免疫功能,提高小鼠机体的免疫力,一定程度地减轻四氧嘧啶的毒性作用,降低血糖。     

Microbial oxidation of arsenite in a subarctic environment: diversity of arsenite oxidase genes and identification of a psychrotolerant arsenite oxidiser

Background  

Arsenic is toxic to most living cells. The two soluble inorganic forms of arsenic are arsenite (+3) and arsenate (+5), with arsenite the more toxic. Prokaryotic metabolism of arsenic has been reported in both thermal and moderate environments and has been shown to be involved in the redox cycling of arsenic. No arsenic metabolism (either dissimilatory arsenate reduction or arsenite oxidation) has ever been reported in cold environments (i.e. < 10°C).     

Synergistic toxicity between arsenic and methylated selenium compounds

Arsenite has been known for half a century to have a protective effect against selenium poisoning. Paradoxically, arsenite inhibits the conversion of inorganic selenium salts to methylated excretory products, although methylation has long been regarded as a detoxification mechanism for selenium. Moreover, there is evidence for a pronounced synergistic toxicity between arsenite and methylated selenium metabolites. We investigated the effect of arsenite on the acute toxicity of a variety of methylated or nonmethylated selenium compounds, as well as methylated forms of sulfur and tellurium. Adult male rats were injected with sodium arsenite (4 mg As/kg bw, s.c.) 10 min prior to injection of the test compounds; at the doses employed, none of the test compounds caused mortality, nor did arsenite, when given alone. When given with arsenite, the following methylated compounds produced toxic signs and high morality at the indicated dosages (mg Se/kg): Methylseleninic acid (2), dimethylselenoxide (2), trimethylselenonium chloride (3), selenobetaine (2), selenobetaine methylester (2, also 1 and 0.5), and Se-methylselenocysteine (2). Toxic signs but not mortality occurred when arsenite was given with selenomethionine (2 mg Se/kg). No enhancement of toxic signs or mortality occurred when arsenite was given with sulfobetaine (0.8 mg S/kg), dimethylsulfide (320 mg S/kg), or the following (nonmethylated) forms of selenium: sodium selenite (2), selenocystine (2), and phenylselenol (2). Arsenite also increased the toxicity of trimethyltelluronium chloride (4.8 mg Te/kg). Like arsenite, periodate-oxidized adenosine (100 mumoles/kg), which is known to inhibit the formation of dimethylselenide and trimethylselenonium ion in vivo, caused increased 24 h mortality when given with various methylated selenium compounds.(ABSTRACT TRUNCATED AT 250 WORDS)