Surface-coupled proton exchange of a membrane-bound proton acceptor

Sandén, Tor; Salomonsson, Lina; Brzezinski, Peter; Widengren, Jerker

doi:10.1073/pnas.0908671107

Cited by 57 publications

(90 citation statements)

References 31 publications

(34 reference statements)

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“…A section through a c 6 segment of the B. pseudofirmus OF4 c 13 ring with marked Cα positions of the alanines within the alkaliphilespecific 16 AxAxAxA 22 stretch shows this motif as a notable feature and the tight c-subunit packing (Fig. 1B).…”

Section: Resultsmentioning

confidence: 99%

The c-ring stoichiometry of ATP synthase is adapted to cell physiological requirements of alkaliphilic Bacillus pseudofirmus OF4

Preiß

Klyszejko

Hicks

et al. 2013

Proc. Natl. Acad. Sci. U.S.A.

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The c-rings of ATP synthases consist of individual c-subunits, all of which harbor a conserved motif of repetitive glycine residues (GxGxGxG) important for tight transmembrane α-helix packing. The cring stoichiometry determines the number of ions transferred during enzyme operation and has a direct impact on the ion-to-ATP ratio, a cornerstone parameter of cell bioenergetics. In the extreme alkaliphile Bacillus pseudofirmus OF4, the glycine motif is replaced by AxAxAxA. We performed a structural study on two mutants with alanine-to-glycine changes using atomic force microscopy and X-ray crystallography, and found that mutants form smaller c 12 rings compared with the WT c 13 . The molar growth yields of B. pseudofirmus OF4 cells on malate further revealed that the c 12 mutants have a considerably reduced capacity to grow on limiting malate at high pH. Our results demonstrate that the mutant ATP synthases with either c 12 or c 13 can support ATP synthesis, and also underscore the critical importance of an alanine motif with c 13 ring stoichiometry for optimal growth at pH >10. The data indicate a direct connection between the precisely adapted ATP synthase c-ring stoichiometry and its ionto-ATP ratio on cell physiology, and also demonstrate the bioenergetic challenges and evolutionary adaptation strategies of extremophiles.

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Section: Resultsmentioning

confidence: 99%

The c-ring stoichiometry of ATP synthase is adapted to cell physiological requirements of alkaliphilic Bacillus pseudofirmus OF4

Preiß

Klyszejko

Hicks

et al. 2013

Proc. Natl. Acad. Sci. U.S.A.

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“…2, upon reconstitution of CytcO into the membrane, the rate constant increased from ∼830 s −1 to ∼5;900 s −1 (at pH 9.5), i.e., by a factor of 7, in agreement with an earlier study with the P. denitrificans CytcO (33). We per- formed the studies at high pH (9.5) because at this pH, the extent of the PCET displays a maximum and also the effect of the membrane on the proton-transfer rate increases with increasing pH (34). To test whether the acceleration of the PCET was due to a change in conductivity of the proton pathway or due to specific interactions with the membrane surface, we investigated the PCET in a number of mutant CytcOs in which residues within the pathway or at the surface near the pathway orifice were modified (summarized in Table 1).…”

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confidence: 99%

Functional interactions between membrane-bound transporters and membranes

Öjemyr

Lee

Gennis

et al. 2010

Proc. Natl. Acad. Sci. U.S.A.

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One key role of many cellular membranes is to hold a transmembrane electrochemical ion gradient that stores free energy, which is used, for example, to generate ATP or to drive transmembrane transport processes. In mitochondria and many bacteria, the gradient is maintained by proton-transport proteins that are part of the respiratory (electron-transport) chain. Even though our understanding of the structure and function of these proteins has increased significantly, very little is known about the specific role of functional protein-membrane and membrane-mediated proteinprotein interactions. Here, we have investigated the effect of membrane incorporation on proton-transfer reactions within the membrane-bound proton pump cytochrome c oxidase. The results show that the membrane acts to accelerate proton transfer into the enzyme's catalytic site and indicate that the intramolecular proton pathway is wired via specific amino acid residues to the twodimensional space defined by the membrane surface. We conclude that the membrane not only acts as a passive barrier insulating the interior of the cell from the exterior solution, but also as a component of the energy-conversion machinery.cytochrome aa3 | electron transfer | energy transduction | membrane protein | respiration

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“…The recent work by our group (Brändén et al 2006), (Öjemyr et al, 2009), (Persson et al, 2009), (Sandén et al, 2010) …”

Section: Acknowledgementsmentioning

confidence: 88%

“…). In analogy with this, similar charge screening effects have been analysed by FCS for protonation kinetics at biological membranes (Sandén et al, 2010) and for fluorescence quenching of fluorophores close to dielectric interfaces (Blom et al, 2010). However, since this charge screening affects the interaction between buffer molecules and fluorophores, no particular effect of ionic strength on k P is seen in the absence of a buffer, as illustrated in the inset of figure 2B, showing the relaxation rates measured at different concentrations of sodium chloride, with no buffer added.…”

Section: Monitoring Of Local Ion Concentrations and Exchange In Solutionmentioning

confidence: 99%

“…Extending the range of pH over which the protonation kinetics of fluorescein-labelled lipids in liposomes were measured, two different proton exchange regimes could be identified (Sandén et al, 2010). At high pH (>8) the k +1 rate strongly increases with increasing proton concentrations, whereas at low pH (<7) the increase of the k +1 rate with increasing bulk [H + ]…”

Section: Figurementioning

confidence: 99%

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Studying Ion Exchange in Solution and at Biological Membranes by FCS

Widengren

2013

Methods in Enzymology

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By FCS, a wide range of processes can be studied, covering time ranges from subnanoseconds to seconds. In principle, any process at equilibrium conditions can be measured, which reflects itself by a change in the detected fluorescence intensity. In this review, it is described how FCS and variants thereof can be used to monitor ion exchange, in solution and along biological membranes. Analysing fluorescence fluctuations of ion sensitive fluorophores by FCS offers selective advantages over other techniques for measuring local ion concentrations, and in particular for studying exchange kinetics of ions on a very local scale. This opens for several areas of application. The FCS approach was used to investigate fundamental aspects of proton exchange at and along biological membranes. The protonation relaxation rate, as measured by FCS for a pH-sensitive dye can also provide information about local accessibility/interaction of a particular labeling site and conformational states of biomolecules, in a similar fashion as in a fluorescence quenching experiment. Beyond protonation kinetics, the same FCS concept can also be applied to ion exchange studies using other ion sensitive fluorophores, and by use of dyes sensitive to other ambient conditions the concept can be extended also beyond ion exchange studies.3

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Surface-coupled proton exchange of a membrane-bound proton acceptor

Cited by 57 publications

References 31 publications

The c-ring stoichiometry of ATP synthase is adapted to cell physiological requirements of alkaliphilic Bacillus pseudofirmus OF4

The c-ring stoichiometry of ATP synthase is adapted to cell physiological requirements of alkaliphilic Bacillus pseudofirmus OF4

Functional interactions between membrane-bound transporters and membranes

Studying Ion Exchange in Solution and at Biological Membranes by FCS

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