On the involvement of electron transfer reactions in the fluorescence decay kinetics heterogeneity of proteins

Ababou, Abdessamad; Bombarda, Elisa

doi:10.1110/ps.05501

Cited by 37 publications

(36 citation statements)

References 92 publications

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“…As tryptophan residue becomes hydrogen bonded or exposed to water its emission spectra and quantum yield is changed. There are several factors that determine the emission from tryptophan residues of protein molecules such as (1) quenching by proton transfer from nearby charged amino groups, (2) quenching by electron acceptors such as protonated carboxyl groups, (3) electron transfer quenching by disulfides and amides, (4) electron transfer quenching by peptide bonds in the protein backbone, and (5) resonance energy transfer among the tryptophan residues [16][17][18][19][20][21]. Additionally, a protein may exist in more than a single conformation, with each displaying a different quantum yield.…”

Section: Discussionmentioning

confidence: 99%

Variation of fluorescence in tissue with temperature

et al. 2011

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Section: Discussionmentioning

confidence: 99%

Variation of fluorescence in tissue with temperature

et al. 2011

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“…In the nervous system, ATP acts as an excitatory neurotransmitter in many regions of the CNS [7,[19][20][21][22][23]; in the periphery, ATP is known to activate nociceptive fibers and produce pain sensation [3,16]. Rapid excitatory effects of ATP are mediated through multigene family of P2X [1][2][3][4][5][6][7] receptors, which open the cation-selective ion-conducting pore upon agonist binding [15,17]. Purinoreceptors of P2X 3 subtype are expressed almost exclusively in mammalian sensory neurons and are thought to serve several specific functions from coding temperature sensation to nociception [18,29].…”

Section: Introductionmentioning

confidence: 99%

P2X3 receptor gating near normal body temperature

Khmyz

Maximyuk

Teslenko

et al. 2007

Pflugers Arch - Eur J Physiol

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P2X3 purinoreceptors expressed in mammalian sensory neurons are involved in nociception, mechanosensory transduction, and temperature sensation. Homomeric P2X3 receptors desensitize rapidly (<500 ms after activation by an agonist) and recover from desensitization very slowly (20-25 min at room temperature). They are susceptible to use-dependent inhibition by low nanomolar concentrations of ATP through developing the "high-affinity binding site" (HABS), which traps ATP molecules, thus keeping receptors in a desensitized state (Pratt et al., J Neurosci 25:7359-7365, 2005). Indeed, here we demonstrated directly that the desensitization of the receptor, after being activated by ATP, proceeds independently of the presence of agonist. We found that the temperature sensitivity of P2X3 receptors is abnormal: development of desensitization does not depend on temperature within the range between 25 and 40 degrees C, whereas the recovery from desensitization is greatly \accelerated with temperature increase (Q10 approximately 10). The sensitivity of HABS to low nanomolar ATP near normal body temperature (35 degrees C) is substantially lower than at 25 degrees C (IC50 is 3.2+/-0.3 nM at 35 degrees C and 0.79+/-0.09 nM at 25 degrees C). HABS itself is subjected to slow desensitization partially loosing its sensitivity to ATP: at 35 degrees C the response completely recovers in 10 min in the presence of 3 nM ATP, making the receptor operational in the presence of up to 30 nM ATP. Unusual combination of temperature sensitivity/insensitivity of P2X3 receptors may be related to their pivotal role in the processing of thermal sensitivity as revealed by recent knockout experiments.

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“…electron transfer (and/or hole transfer) or fluorescence resonance energy transfer (FRET) from excited tryptophan and/or tyrosine residues. Since no indication for energy acceptors for FRET in proteins have been found [23], we consider fluorescence decay modeling which involves electron transport processes. The general idea is that the electron of an excited fluorophore can migrate (with a transfer rate ν(t)) to some excited states different from the initial one.…”

Section: Excitation Transportmentioning

confidence: 99%

“…One example of such a process in proteins is electron transport to a neighboring quenching residue. Many possible electron acceptors have been proposed, such as a peptide bond carbonyl group [23] (due to appearance of a net positive charge on the peptide bond carbonyl carbon [24]) or amino acid residues involved in π−π stacking interaction. Since almost all amino acid side chains are more or less effective quenchers [10,25], the proposed model is applicable to proteins in general.…”

Section: Excitation Transportmentioning

confidence: 99%

Fluorescence Decay Heterogeneity Model Based on Electron Transfer Processes in an Enzyme-Ligand Complex

Włodarczyk

Kierdaszuk

2005

Acta Phys. Pol. A

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The models are described for complex fluorescence decay of tyrosine in proteins involving continuous distribution of fluorescence lifetimes and electron transfer processes. We introduce the analytical decay function with a power-like term, which provides good fits to highly complex fluorescence decays. Moreover, the power-like term in the proposed decay functions is a manifestation of so-called Tsallis nonextensive statistics and is suitable for description of the systems with long-range interactions, memory effect, as well as with fluctuations of the characteristic lifetime of fluorescence. The proposed decay functions were applied to analysis of fluorescence decays of tyrosine in a protein, i.e. the enzyme purine nucleoside phosphorylase from E. coli, free in aqueous solution and in the complex with formycin A (an inhibitor) and orthophosphate (a co-substrate), and demonstrated that both models reflect the enzyme−ligand interactions. Direct measure of heterogeneity of the enzyme systems is provided by a variance of fluorescence lifetime distribution. The possible number of deactivation channels and excited state mean lifetime can be easily derived without a priori knowledge of the complexity of studied system.

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On the involvement of electron transfer reactions in the fluorescence decay kinetics heterogeneity of proteins

Cited by 37 publications

References 92 publications

Variation of fluorescence in tissue with temperature

Variation of fluorescence in tissue with temperature

P2X3 receptor gating near normal body temperature

Fluorescence Decay Heterogeneity Model Based on Electron Transfer Processes in an Enzyme-Ligand Complex

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