Thermodynamics of proton transfer reactions in the gas phase

Fernandez, M. T. N.

January 1986

No description available.

539.7

Proton transfer equilibria

Photoexcited hydroxyarenes as probes for microenvironments

Sullivan, Erica N.

05 1900

No description available.

Photochemistry

Proton transfer reactions

Proton-transfer dynamics of novel photoexcited hydroxyarenes

Clower, Caroline Elizabeth

12 1900

No description available.

Proton transfer reaction

Photochemistry

Structural elements involved in protein-mediated proton transfer : Implications from studies of cytochrome c oxidase

Johansson, Ann-Louise

January 2013

Proton transfer is one of the most common reactions in biological systems. During energy conversion inside a cell, proton transfer is crucial to maintain an electrochemical proton gradient across the cell membrane. This gradient is in turn used to e.g. produce ATP, the energy currency of the cell. One of the key components of the build-up of this gradient is cytochrome c oxidase. This membrane-bound enzyme catalyzes the reduction of molecular oxygen to water, using protons and electrons, and in the process protons are pumped across the membrane. All protons used during oxygen reduction and those that are pumped, are transferred via hydrophilic pathways inside the hydrophobic interior of the enzyme. One of these pathways, called the D pathway, is used to transfer protons both to the catalytic site and towards a pump site. It is yet not fully understood how these proton-transfer reactions are timed, coupled and controlled.   This thesis is focused on studies of proton-transfer reactions through the D pathway in variants of cytochrome c oxidase that lack the ability to pump protons. The results suggest that changes in pKa values of key residues, as well as structural changes inside the pathway, can explain the non-pumping phenotypes. The results have led us to propose that an internal proton shuttle (Glu286I) can adopt two different conformations that are in equilibrium with each other, and that this equilibrium is altered in non-pumping variants of cytochrome c oxidase. We also observed that proton transfer through the D pathway could occur with the same rate as in the wild-type enzyme even when one of the key residues (Asp132I) is absent. This result contradicts previous assumptions that acidic residues must be present at an orifice of proton pathways. We therefore suggest that this specific residue could have an additional role, e.g. as a selectivity filter that excludes all ions except protons from entering the pathway. / <p>At the time of doctoral defence the following papers were unpublished and had a status as follows: Paper 2: Accepted; Paper 3: Manuscript</p>

cytochrome c oxidase

proton transfer

Excited state proton transfer in microheterogeneous conditions

Linares-Samaniego, Sandra I.

05 1900

No description available.

Proton transfer reactions

Chemical reactions

The effect of structure on kinetic isotope effects

Goodall, D. M.

January 1965

No description available.

Membrane effects on proton transfer in cytochrome c oxidase

Näsvik Öjemyr, Linda

January 2012

The biological membrane is composed of lipids and proteins that make up dynamic barriers around cells and organelles. Membrane-spanning proteins are involved in many key processes in the cell such as energy conversion, nerve conduction and signal transduction. These proteins interact closely with lipids as well as with other proteins in the membrane, which modulates and affects their structure and function. In the energy-conversion process, membrane-bound proton-transport proteins maintain an electrochemical proton gradient across the mitochondrial inner membrane or the cytoplasmic membrane of bacteria. This gradient is utilized for ATP synthesis or transport of ions and molecules across the membrane. Results from earlier studies have shown that proton transporters are influenced by their environment. Here, one of these proton transporters, cytochrome c oxidase, has been purified and reconstituted into liposomes or nanodiscs and membrane effects on specific proton-transfer processes were studied. In these studies we observed that the membrane accelerated proton transfer to the surface of cytochrome c oxidase and that there is a protonic link, via a Glu residue that mediates proton transfer from the membrane surface to a proton-transfer pathway in this protein. In addition, the membrane was shown to modulate specific internal electron and proton-transfer reactions. The results from these studies show that the membrane composition influences transmembrane transport. Consequently, our understanding of these processes requires investigation of these transporter proteins in different membrane-mimetic systems of variable and well-defined composition. Furthermore, the data show that membrane surfaces facilitate lateral proton transfer which is presumably essential for maintaining high efficiency in energy conversion. This is particular important in organisms such as alkaliphilic bacteria where the driving force of the electrochemical proton gradient, between the bulk solution on each side of the membrane is not sufficient for ATP synthesis.

cytochrom c oxidase

lipids

membrane

proton transfer

Proton-coupled electron transfer and tyrosine D of phototsystem II

Jenson, David L. Jenson.

January 2009

Thesis (Ph. D.)--Chemistry and Biochemistry, Georgia Institute of Technology, 2010. / Committee Chair: Bridgette Barry; Committee Member: Ingeborg Schmidt-Krey; Committee Member: Jake Soper; Committee Member: Nils Kroger; Committee Member: Wendy Kelly. Part of the SMARTech Electronic Thesis and Dissertation Collection.

Excited state proton transfer in ortho substituted naphthols : Part II Mechanistic studies of ortho allyl-naphthol photocyclizations

Harvey, Lilia Cuesta

12 1900

No description available.

Photochemistry

Chemical reactions

Proton transfer reactions

N-methyl-6-hydroxyquinolinium: an investigation into the spectroscopy and applications of excited-state proton transfer

Salvitti, Michael Anthony

11 July 2008

N-methyl-6-hydroxyquinolinium (NM6HQ) is a powerful excited-state proton donor, exhibiting a huge pKa drop from 7.2 in the ground state to -7 in the excited state. The zwitterionic nature of the proton transfer product encourages intramolecular electron transfer away from the hydroxyl moiety to the distal ring, allowing for a large pKa jump in the excited state. This process is reversible, making the NM6HQ salts powerful transient superacids. We have investigated the excited-state proton transfer (ESPT) from NM6HQ salts to various basic solvents (alcohols, DMSO). A model has been developed that adequately describes the ion-dipole interactions in the ESPT geminate-recombination process. Our studies have shown that the counterion plays a large role in the ESPT. Likewise, initiation of cationic polymerization is controlled by the counterion. NM6HQ perfluoroalkylsulfonates appear to be the first molecules reported which are capable of initiating aliphatic epoxide polymerization at room temperature through a proton transfer mechanism.

PTTS

Proton transfer to solvent

ESPT

Excited-state proton transfer

Proton transfer

Counterion effects

Photoacid generator

PAG

Anion effects

Proton transfer reactions

Excited state chemistry

Photopolymerization

Polymerization