{"id":13882,"date":"2020-03-25T11:18:13","date_gmt":"2020-03-25T03:18:13","guid":{"rendered":"https:\/\/www.bihec.com\/olisclarity\/?p=13882"},"modified":"2020-03-25T11:18:13","modified_gmt":"2020-03-25T03:18:13","slug":"olis-clarity-1000a%e5%85%89%e8%b0%b1%e4%bb%aa%e5%ba%94%e7%94%a8%e8%ae%ba%e6%96%87","status":"publish","type":"post","link":"https:\/\/www.bihec.com\/olisclarity\/olis-clarity-1000a%e5%85%89%e8%b0%b1%e4%bb%aa%e5%ba%94%e7%94%a8%e8%ae%ba%e6%96%87\/","title":{"rendered":"Olis CLARiTY 1000A\u5149\u8c31\u4eea\u5e94\u7528\u8bba\u6587"},"content":{"rendered":"

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In situ<\/i>\u00a0spectroscopy on intact\u00a0Leptospirillum ferrooxidans<\/i>\u00a0reveals that reduced cytochrome 579 is an obligatory intermediate in the aerobic iron respiratory chain<\/h1>\n
Robert C. Blake II<\/a>* and\u00a0 Megan N. Griff<\/a><\/div>\n
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College of Pharmacy, Xavier University of Louisiana, New Orleans, LA, USA<\/li>\n<\/ul>\n
Electron transfer reactions among colored cytochromes in intact bacterial cells were monitored using an integrating cavity absorption meter that permitted the acquisition of accurate absorbance data in suspensions of cells that scatter light. The aerobic iron respiratory chain of\u00a0Leptospirillum ferrooxidans<\/i>\u00a0was dominated by the redox status of an abundant cellular cytochrome that had an absorbance peak at 579 nm in the reduced state. Intracellular cytochrome 579 was reduced within the time that it took to mix a suspension of the bacteria with soluble ferrous iron at pH 1.7. Steady state turnover experiments were conducted where the initial concentrations of ferrous iron were less than or equal to that of the oxygen concentration. Under these conditions, the initial absorbance spectrum of the bacterium observed under air-oxidized conditions was always regenerated from that of the bacterium observed in the presence of Fe(II). The kinetics of aerobic respiration on soluble iron by intact\u00a0L. ferrooxidans<\/i>\u00a0conformed to the Michaelis\u2013Menten formalism, where the reduced intracellular cytochrome 579 represented the Michaelis complex whose subsequent oxidation appeared to be the rate-limiting step in the overall aerobic respiratory process. The velocity of formation of ferric iron at any time point was directly proportional to the concentration of the reduced cytochrome 579. Further, the integral over time of the concentration of the reduced cytochrome was directly proportional to the total concentration of ferrous iron in each reaction mixture. These kinetic data obtained using whole cells were consistent with the hypothesis that reduced cytochrome 579 is an obligatory steady state intermediate in the iron respiratory chain of this bacterium. The capability of conducting visible spectroscopy in suspensions of intact cells comprises a powerful post-reductionist means to study cellular respiration\u00a0in situ<\/i>\u00a0under physiological conditions for the organism.<\/p>\n
<\/div>\n<\/div>\n<\/a><\/p>\n
Introduction<\/h2>\n
Certain chemolithotrophic bacteria inhabit ore-bearing geological formations exposed to the atmosphere and obtain all of their energy for growth from the oxidation and dissolution of minerals within the ore. Energy is derived from oxidative phosphorylation coupled to respiratory electron transfer. The ability to respire aerobically on soluble ferrous ions under strongly acidic conditions is currently known to be expressed by at least 34 species in 14 genera distributed throughout the Gram-negative (Markosyan, 1972<\/a>;\u00a0 Huber and Stetter, 1989<\/a>;\u00a0 Kelly and Wood, 2000<\/a>;\u00a0 Hallberg et al., 2010<\/a>), Gram-positive (Clark and Norris, 1996<\/a>;\u00a0 Norris et al., 1996<\/a>;\u00a0 Johnson et al., 2008<\/a>,\u00a0 2009<\/a>;\u00a0 Guo et al., 2009<\/a>;\u00a0 Jiang et al., 2009<\/a>), and Archaea bacteria (Segerer et al., 1986<\/a>;\u00a0 Huber et al., 1989<\/a>;\u00a0 Huber and Stetter, 1991<\/a>;\u00a0 Karavaiko et al., 1994<\/a>;\u00a0 Golyshina et al., 2000<\/a>,\u00a0 2009<\/a>). Given the genetic diversity within this collection of phenotypically related bacteria, it would not be surprising to learn that phylogenetically distinct groups of bacteria express different electron transfer biomolecules and pathways to accomplish aerobic respiration on soluble iron.<\/p>\n
Classic reductionist studies that involve the structural and functional characterization of highly purified proteins in dilute solution have described a bewildering variety of different redox-active electron transport proteins in cell-free extracts derived from iron-grown Gram-negative (Cox and Boxer, 1978<\/a>;\u00a0 Hart et al., 1991<\/a>;\u00a0 Blake et al., 1992<\/a>;\u00a0 Yarz\u00e1bal et al., 2002<\/a>,\u00a0 2004<\/a>), Gram-positive (Blake et al., 1993<\/a>;\u00a0 Takai et al., 2001<\/a>;\u00a0 Dinarieva et al., 2010<\/a>), and Archaea (Hettmann et al., 1998<\/a>;\u00a0 Dopson et al., 2005<\/a>;\u00a0 Auernik and Kelly, 2008<\/a>) bacteria. The most promising efforts to date have focused on the iron respiratory chain of\u00a0Acidithiobacillus ferrooxidans<\/i>, where an iron \u201crespirasome\u201d super complex has been defined that is comprised of 2\u00a0c<\/i>-type cytochromes, a blue copper protein called rusticyanin, and an\u00a0aa_{3<\/sub><\/i>-type terminal oxidase (}Castelle et al., 2008<\/a>). The proteins in the aerobic iron respiratory pathway of\u00a0At. ferrooxidans<\/i>\u00a0do not appear to be expressed in many of the phylogenetically distinct bacteria that also respire on iron. Similarly, redox-active proteins expressed in other iron-grown bacteria do not appear to be expressed in iron-grown\u00a0At. ferrooxidans<\/i>. Comparative analyses conducted using those relevant bacterial genomes where partial or complete DNA sequence data is available (Chen et al., 2005<\/a>;\u00a0 Ram et al., 2005<\/a>;\u00a0 Valdes et al., 2008<\/a>;\u00a0 Clum et al., 2009<\/a>;\u00a0 Siezen and Wilson, 2009<\/a>) have not yet provided significant insight into other iron respiratory proteins or pathways. There is little information in the DNA databases to compare with because the proteins in the aerobic iron respiratory pathway of\u00a0At. ferrooxidans<\/i>\u00a0do not appear to be universal among those bacteria that respire on iron. In either case, actual respiratory electron transfer in the intact organism is not directly observed. Rather, the functional properties of the intact electron transfer chain are inferred from observations on isolated molecules.<\/p>\n
This paper introduces a new means to study respiratory electron transfer reactions\u00a0in situ<\/i>\u00a0in intact bacteria under physiological conditions. The premise is that accurate UV-visible spectroscopy of electron transfer reactions among colored cytochromes can be conducted in highly turbid suspensions if the live bacteria are irradiated in an isotropic homogeneous field of incident measuring light. Under those conditions, the absorbed radiant power is independent of scattering effects (Elterman, 1970<\/a>;\u00a0 Fry et al., 1992<\/a>;\u00a0 Javorfi et al., 2006<\/a>;\u00a0 Hodgkinson et al., 2009<\/a>). We conducted equilibrium and kinetic studies on the Fe(II)-dependent reduction and O_{2<\/sub>-dependent oxidation of cytochromes in intact\u00a0Leptospirillum ferrooxidans<\/i>\u00a0at pH 1.7. We used a commercial integrating cavity absorption meter (ICAM) where the cuvette comprised a reflecting cavity completely filled with the absorbing suspension.\u00a0L. ferrooxidans<\/i>\u00a0was selected because it is only known to respire on one substrate, reduced iron (}Harrison, 1984<\/a>). We observed that a cytochrome with a reduced spectral peak at 579 nm is an obligatory intermediate in the aerobic iron respiratory chain of\u00a0L. ferrooxidans<\/i>.<\/p>\n
<\/a><\/p>\n
Materials and Methods<\/h2>\n
Cell Culture<\/h3>\n
Leptospirillum ferrooxidans<\/i>\u00a0DSMZ 2705 was cultured autotrophically on soluble ferrous ions at 30\u00b0C in the medium described elsewhere (Tuovinen and Kelly, 1973<\/a>), adjusted to pH 1.5 and amended with 44 g\/l of FeSO_{4<\/sub>\u00b77H_{2<\/sub>O. Cells grown to stationary phase were harvested by centrifugation, washed three times with 0.02 M H_{2<\/sub>SO_{4<\/sub>, pH 1.7, and resuspended in sufficient 0.02 M H_{2<\/sub>SO_{4<\/sub>\u00a0to achieve a stock suspension of 1.5 \u00d7 10^{10<\/sup>\u00a0cells\/ml. The stock suspension was stored at 4\u00b0C for up to 2 weeks while spectroscopic experiments were conducted on aliquots of the cells. Previous stock suspensions of this organism have been stored in dilute sulfuric acid at 4\u00b0C for over 6 weeks before changes in the bacterium\u2019s energy metabolism could be detected.<\/p>\n}}}}}}}
Quantification of Bacteria<\/h3>\n
Absolute numbers of\u00a0L. ferrooxidans<\/i>\u00a0cells were determined by electrical impedance measurements in a Multisizer 4 particle counter (Beckman Coulter, Inc., Brea, CA, USA) fitted with a 30-\u03bcm aperture. The instrument was programmed to siphon 50 \u03bcl of sample that contained Isoton II as the electrolyte. The current applied across the aperture was 600 \u03bcA. Voltage pulses attendant with impedance changes as particles passed through the aperture were monitored with an instrument gain of four.<\/p>\n
Relative numbers of\u00a0L. ferrooxidans<\/i>\u00a0cells were determined by photon correlation scattering spectroscopy with a DelsaNano C particle size analyzer, also from Beckman Coulter, Inc. Cell densities were adjusted to 8.3 \u00d7 10^{6<\/sup>\u00a0cells\/ml in 0.02 M sulfuric acid to give an attenuator obscuration of 47%. Determination of the relative numbers of light scattering species as a function of particle diameter was accomplished by the time domain method with operating and analysis software provided by Beckman Coulter, Inc.<\/p>\n}
Absorbance Measurements with Cell Suspensions<\/h3>\nAbsorbance measurements on intact cells in suspension were conducted in an Olis<\/a> CLARiTY 1000<\/a> A spectrophotometer (On Line Instrument Systems, Inc., Bogart, GA, USA) that employed a novel ICAM. In a typical experiment, identical 4.2 ml solutions that contained ferrous sulfate in 0.02 M sulfuric acid, pH 1.7, were added to both the sample and reference observation cavities of the spectrophotometer. After recording a stable baseline from 350 to 650 nm, 140 \u03bcl were withdrawn from the sample cavity and replaced with 140 \u03bcl of the stock cell suspension of\u00a0L. ferrooxidans<\/i>. Apparent absorbance spectra (typically 6.2 s^{\u22121<\/sup>) were then collected until any visible absorbance changes had ceased. Raw apparent absorbance values were converted to absorbance values per cm using Fry\u2019s method (}Fry et al., 2010<\/a>) as described in the text.<\/p>\n
<\/a><\/p>\n
Results<\/h2>\n
The Redox State of Electron Transfer Proteins Can be Monitored\u00a0in situ<\/i>\u00a0in Intact Bacteria under Physiological Conditions<\/h3>\n
The principal features of the novel CLARiTY spectrophotometer used to conduct absorbance measurements in turbid solutions are included in the schematic diagram shown in Figure\u00a0 1<\/a>. The sample and reference observation cells of this dual beam spectrophotometer were each comprised of a 4.2-ml spherical quartz cuvette fused with a 6-mm ID quartz tube. Each quartz chamber was surrounded by a tightly packed proprietary white powder that served to maximize diffuse reflectance of light on the exterior walls of the spherical flask. The apertures in the reflecting sphere through which the measuring light entered and the transmitted\/scattered light exited to the photomultiplier tube were positioned at a 90\u00b0 angle such that the light had to undergo many reflections and cell transversals before it was quantified using the photomultiplier tube. A white Teflon plug with a 6-mm OD was inserted into the quartz tube to minimize the loss of light out of the neck. A 1.0-cm white stir bar was included in the sample chamber to facilitate sample mixing and suspension of any particulate matter.<\/p>\n<\/div>\n
CD\u5149\u8c31\u4eea<\/a>\n CD\u5706\u4e8c\u8272\u5149\u8c31\u4eea<\/a>\n CPL\u5706\u504f\u632f\u5149\u8c31\u4eea<\/a>\n DSM CD<\/a>\n Olis<\/a>\n \u5149\u8c31\u4eea\u5206\u6790\u4eea<\/a>\n \u5149\u8c31\u5206\u6790\u4eea\u4ef7\u683c<\/a>\n \u5404\u5411\u5f02\u6027\u68c0\u6d4b<\/a>\n \u56fa\u4f53\u6837\u54c1\u900f\u5c04\u4e0e\u53cd\u5c04\u68c0\u6d4b<\/a>\n \u5706\u4e8c\u8272\u5149\u8c31\u4eea<\/a>\n \u86cb\u767d\u5706\u4e8c\u8272\u8c31<\/a><\/div>","protected":false},"excerpt":{"rendered":"
In situ\u00a0spectroscopy on intact\u00a0Leptospirillum ferrooxidans\u00a0reveals that reduced cytochrome <\/p>\n","protected":false},"author":19,"featured_media":111,"comment_status":"open","ping_status":"open","sticky":false,"template":"","format":"standard","meta":[],"categories":[90,1],"tags":[15,24,8,71,5,23,30,69,68,4,13],"_links":{"self":[{"href":"https:\/\/www.bihec.com\/olisclarity\/wp-json\/wp\/v2\/posts\/13882"}],"collection":[{"href":"https:\/\/www.bihec.com\/olisclarity\/wp-json\/wp\/v2\/posts"}],"about":[{"href":"https:\/\/www.bihec.com\/olisclarity\/wp-json\/wp\/v2\/types\/post"}],"author":[{"embeddable":true,"href":"https:\/\/www.bihec.com\/olisclarity\/wp-json\/wp\/v2\/users\/19"}],"replies":[{"embeddable":true,"href":"https:\/\/www.bihec.com\/olisclarity\/wp-json\/wp\/v2\/comments?post=13882"}],"version-history":[{"count":1,"href":"https:\/\/www.bihec.com\/olisclarity\/wp-json\/wp\/v2\/posts\/13882\/revisions"}],"predecessor-version":[{"id":13883,"href":"https:\/\/www.bihec.com\/olisclarity\/wp-json\/wp\/v2\/posts\/13882\/revisions\/13883"}],"wp:featuredmedia":[{"embeddable":true,"href":"https:\/\/www.bihec.com\/olisclarity\/wp-json\/wp\/v2\/media\/111"}],"wp:attachment":[{"href":"https:\/\/www.bihec.com\/olisclarity\/wp-json\/wp\/v2\/media?parent=13882"}],"wp:term":[{"taxonomy":"category","embeddable":true,"href":"https:\/\/www.bihec.com\/olisclarity\/wp-json\/wp\/v2\/categories?post=13882"},{"taxonomy":"post_tag","embeddable":true,"href":"https:\/\/www.bihec.com\/olisclarity\/wp-json\/wp\/v2\/tags?post=13882"}],"curies":[{"name":"wp","href":"https:\/\/api.w.org\/{rel}","templated":true}]}}