High probability of disrupting a disulphide bridge mediated by an endogenous excited tryptophan residue

Neves‐Petersen, Maria Teresa; Gryczyński, Zygmunt; Lakowicz, Joseph R.; Fojan, Peter; Pedersen, Shona; Petersen, Evamaria; Petersen, Steffen B.

doi:10.1110/ps.06002

Cited by 132 publications

(115 citation statements)

References 33 publications

(61 reference statements)

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“…Therefore, in contrast to UV irradiation, the ionized radiation has little or no effect on the number of free SH groups in hair. The disruption of the disulfide bridge nearby the tryptophan residue by UV light excitation of this aromatic residue has been reported in previous studies [14]. Tryptophan excitation energy disrupts a neighboring disulfide bridge, which in turn leads to altered structural integrity and stability.…”

Section: Figure 5 Changes In Content Of Sh-groups Of Human Hair Exposupporting

confidence: 62%

Changes in Human Hair Induced by UV- and Gamma Irradiation

Palma¹,

González‐Gómez²,

Galicia³

et al. 2016

ABB

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The effect of UV-and 137 Cs gamma radiation on the structural and chemical integrity of human hair was studied to determine the feasibility of using human hair as a non-invasive biomarker of radiation exposure to ionized gamma-and non-ionized UV-radiation. Steady state tryptophan (Trp) fluorescence and chemical analytical methods were used to evaluate the molecular integrity of Trp fluorophores and SH-groups in hair proteins and to assess the radiation induced damage quantitatively. It was found that human hair fibers were progressively damaged by exposure to both UV-and ionized gamma radiation. Damage to the hair was evidenced by a decrease in the fluorescence intensity as a result of observed depletion of the amino acid tryptophan as well as significant reduction in a number of free SH-groups in hair proteins. Hair damage was dose-dependent for exposures between 0 and 10.0 Gy and 0 -20 J/cm 2 of UV-radiation. Additional results demonstrate that hair-fibers exposed to gamma rays, with much higher quantum energy than UV, undergo a smaller extent of changes in Trp fluorescence than when exposed to lower or equal energy of UV-irradiation. The stable Trp fluorophore appears to be extremely sensitive to UVradiation in contrast to the ionized gamma radiation whose damage is originated from the reaction of free radicals and direct deposition of energy. We conclude that fluorescence spectroscopy represents a useful tool in the quantitative evaluation of the radiation exposure and could also be used for the rapid and non-invasive assessment of radiation dose i.e. biodosimeter. The approach is simple, non-invasive and appears to have considerable potential that enables quantitative evaluation of radiation dose exposure in a single hair fiber.

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Section: Figure 5 Changes In Content Of Sh-groups Of Human Hair Exposupporting

confidence: 62%

Changes in Human Hair Induced by UV- and Gamma Irradiation

Palma¹,

González‐Gómez²,

Galicia³

et al. 2016

ABB

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“…Microtubules have been shown to reorganize in a dose-dependent manner after exposure to UV light [39][40][41][42], with the greatest effect being observed around 280 nm [42]. Feasible mechanisms for these changes include the reduction of disulfide or peptide bonds induced by photoexcitation of Trp groups [43][44][45][46], or subtle protein structural changes owing to photo-induced alterations in Trp flexibility [46]. Such a signalling mechanism may explain the observed apparent UV mediated cell-to-cell influence on cell division [47].…”

Section: Resultsmentioning

confidence: 99%

The feasibility of coherent energy transfer in microtubules

Craddock

Friesen

Mane

et al. 2014

J. R. Soc. Interface.

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It was once purported that biological systems were far too 'warm and wet' to support quantum phenomena mainly owing to thermal effects disrupting quantum coherence. However, recent experimental results and theoretical analyses have shown that thermal energy may assist, rather than disrupt, quantum coherent transport, especially in the 'dry' hydrophobic interiors of biomolecules. Specifically, evidence has been accumulating for the necessary involvement of quantum coherent energy transfer between uniquely arranged chromophores in light harvesting photosynthetic complexes. The 'tubulin' subunit proteins, which comprise microtubules, also possess a distinct architecture of chromophores, namely aromatic amino acids, including tryptophan. The geometry and dipolar properties of these aromatics are similar to those found in photosynthetic units indicating that tubulin may support coherent energy transfer. Tubulin aggregated into microtubule geometric lattices may support such energy transfer, which could be important for biological signalling and communication essential to living processes. Here, we perform a computational investigation of energy transfer between chromophoric amino acids in tubulin via dipole excitations coupled to the surrounding thermal environment. We present the spatial structure and energetic properties of the tryptophan residues in the microtubule constituent protein tubulin. Plausibility arguments for the conditions favouring a quantum mechanism of signal propagation along a microtubule are provided. Overall, we find that coherent energy transfer in tubulin and microtubules is biologically feasible.

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“…Despite these great developments, the vast majority of the current approaches rely on either light activation or the use of additional reagents such as reducing agents and enzymes 25. However, photomediated methods can be incompatible with specific enzymes and proteins as their secondary structure can be disrupted through irradiation 26, 27, 28. In addition, utilizing light as an external stimuli may limit the monomer pool as strongly absorbing monomers, including chromophores, would be incompatible with these techniques 29, 30.…”

mentioning

confidence: 99%

Copper‐Mediated Polymerization without External Deoxygenation or Oxygen Scavengers

et al. 2018

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As a method for overcoming the challenge of rigorous deoxygenation in copper‐mediated controlled radical polymerization processes [e.g., atom‐transfer radical polymerization (ATRP)], reported here is a simple Cu0‐RDRP (RDRP=reversible deactivation radical polymerization) system in the absence of external additives (e.g., reducing agents, enzymes etc.). By simply adjusting the headspace of the reaction vessel, a wide range of monomers, namely acrylates, methacrylates, acrylamides, and styrene, can be polymerized in a controlled manner to yield polymers with low dispersities, near‐quantitative conversions, and high end‐group fidelity. Significantly, this approach is scalable (ca. 125 g), tolerant to elevated temperatures, compatible with both organic and aqueous media, and does not rely on external stimuli which may limit the monomer pool. The robustness and versatility of this methodology is further demonstrated by the applicability to other copper‐mediated techniques, including conventional ATRP and light‐mediated approaches.

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High probability of disrupting a disulphide bridge mediated by an endogenous excited tryptophan residue

Cited by 132 publications

References 33 publications

Changes in Human Hair Induced by UV- and Gamma Irradiation

Changes in Human Hair Induced by UV- and Gamma Irradiation

The feasibility of coherent energy transfer in microtubules

Copper‐Mediated Polymerization without External Deoxygenation or Oxygen Scavengers

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