Rates of iron(III) reduction coupled to elemental sulfur or tetrathionate oxidation by acidophilic microorganisms and detection of sulfur intermediates

IF 2.5 4区生物学 Q3 MICROBIOLOGY

Research in microbiology Pub Date : 2024-01-01 DOI:10.1016/j.resmic.2023.104110

Anja Breuker, Axel Schippers

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引用次数: 0

Abstract

Bioleaching processes and acid mine drainage (AMD) generation are mainly driven by aerobic microbial iron(II) and inorganic sulfur/compound oxidation. Dissimilatory iron(III) reduction coupled to sulfur/compound oxidation (DIRSO) by acidophilic microorganisms has been described for anaerobic cultures, but iron reduction was observed under aerobic conditions as well. Aim of this study was to explore reaction rates and mechanisms of this process. Cell-specific iron(III) reduction rates for different Acidithiobacillus (At.) strains during batch culture growth or stationary phase with iron(III) (∼40 mM) as electron acceptor and elemental sulfur or tetrathionate as electron donor (1% or 5 mM, respectively) were determined. The rates were highest under anaerobic conditions for the At. ferrooxidans type strain with 6.8 × 10⁶ and 1.1 × 10⁷ reduced iron(III) ions per second per cell for growth on elemental sulfur and tetrathionate, respectively. The iron(III) reduction rates were somehow lower for the anaerobically sulfur grown archaeon Ferroplasma acidiphilum, and lowest for the sulfur grown At. caldus type strain under aerobic conditions (1.7 × 10⁶ and 7.3 × 10⁴ reduced iron(III) ions per second per cell, respectively). The rates for five strains of At. thiooxidans (aerobe) were in between those for At. ferrooxidans (anaerobe) and At. caldus (aerobe). There was no pronounced pH dependence of iron(III) reduction rates in the range of pH 1.0–1.9 for the type strains of all species but rates increased with increasing pH for four other At. thiooxidans strains. Thiosulfate as sulfur intermediate was found for At. ferrooxidans during anaerobic growths on tetrathionate and iron(III) but not during anaerobic growths on elemental sulfur and iron(III), and a small concentration was measured during aerobic growths on tetrathionate without iron(III). For the At. thiooxidans type strain thiosulfate was found with tetrathionate grown cells under aerobic conditions in presence and absence of iron(III), but not with sulfur grown cells. Evidence for hydrogen sulfide production at low pH was found for the At. ferrooxidans as well as the At. thiooxidans type strains during microaerophilic growth on elemental sulfur and for At. ferrooxidans during anaerobic growths on tetrathionate and iron(III). The occurrence of sulfur compound intermediates supports the hypothesis that chemical reduction of iron(III) ions takes place by sulfur compounds released by the microbial cells.

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铁（III）还原与元素硫或四硫酸盐被嗜酸微生物氧化的速率以及硫中间体的检测。

生物浸出过程和酸性矿井排水（AMD）的产生主要由好氧微生物铁（II）和无机硫/化合物氧化驱动。在厌氧培养中，已经描述了通过嗜酸微生物将异源性铁（III）还原与硫/化合物氧化（DIRSO）相结合，但在好氧条件下也观察到了铁还原。本研究的目的是探索该过程的反应速率和机理。测定了不同酸性硫杆菌（At.）菌株在以铁（III）（～40mM）作为电子受体、元素硫或四硫酸盐作为电子供体（分别为1%或5mM）的分批培养生长或固定期的细胞特异性铁（III。在厌氧条件下，氧化亚铁型菌株在元素硫和四硫酸盐上的生长速率最高，每个细胞每秒分别有6.8×106和1.1×107还原铁离子。在好氧条件下，厌氧硫生长的古铁原体嗜酸性菌株的铁（III）还原率较低，而硫生长的At.caldus型菌株的铁还原率最低（每个细胞每秒分别还原1.7×106和7.3×104个铁离子）。五株氧化硫砷（aerobe）的检出率介于氧化亚铁砷（anarobe）和氧化钙砷（aerbe）之间。对于所有物种的类型菌株，在pH 1.0-1.9的范围内，铁（III）还原率没有明显的pH依赖性，但对于其他四种氧化硫At菌株，还原率随着pH的增加而增加。在四硫酸盐和铁（III）的厌氧生长过程中，发现硫代硫酸盐作为氧化亚铁的硫中间体，但在元素硫和铁（Ⅲ）的厌氧增长过程中没有发现，在没有铁（III。对于At.氧化硫型菌株，在存在和不存在铁（III）的有氧条件下，在四硫酸盐生长的细胞中发现硫代硫酸盐，但在硫生长的细胞不发现硫代硫酸盐。在元素硫上的微需氧生长过程中，at.氧化亚铁和at.氧化硫体型菌株以及在四硫酸盐和铁（III）上的厌氧生长过程中发现了在低pH下产生硫化氢的证据。含硫化合物中间体的出现支持了铁（III）离子的化学还原是由微生物细胞释放的含硫化合物进行的假设。

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来源期刊

Research in microbiology 生物-微生物学

CiteScore

4.10

自引率

3.80%

发文量

审稿时长

16 days

期刊介绍： Research in Microbiology is the direct descendant of the original Pasteur periodical entitled Annales de l''Institut Pasteur, created in 1887 by Emile Duclaux under the patronage of Louis Pasteur. The Editorial Committee included Chamberland, Grancher, Nocard, Roux and Straus, and the first issue began with Louis Pasteur''s "Lettre sur la Rage" which clearly defines the spirit of the journal:"You have informed me, my dear Duclaux, that you intend to start a monthly collection of articles entitled "Annales de l''Institut Pasteur". You will be rendering a service that will be appreciated by the ever increasing number of young scientists who are attracted to microbiological studies. In your Annales, our laboratory research will of course occupy a central position, but the work from outside groups that you intend to publish will be a source of competitive stimulation for all of us."That first volume included 53 articles as well as critical reviews and book reviews. From that time on, the Annales appeared regularly every month, without interruption, even during the two world wars. Although the journal has undergone many changes over the past 100 years (in the title, the format, the language) reflecting the evolution in scientific publishing, it has consistently maintained the Pasteur tradition by publishing original reports on all aspects of microbiology.