Arnaud Tron

Polymersome Popping by Light-Induced Osmotic Shock under Temporal, Spatial, and Spectral Control

The light-triggered, programmable rupture of cell-sized vesicles is described, with particular emphasis on self-assembled polymersome capsules. The mechanism involves a hypotonic osmotic imbalance created by the accumulation of photogenerated species inside the lumen, which cannot be compensated owing to the low water permeability of the membrane. This simple and versatile mechanism can be adapted to a wealth of hydrosoluble molecules, which are either able to generate reactive oxygen species or undergo photocleavage. Ultimately, in a multi-compartmentalized and cell-like system, the possibility to selectively burst polymersomes with high specificity and temporal precision and to consequently deliver small encapsulated vesicles (both polymersomes and liposomes) is demonstrated.

Water-soluble naphthalimide-based ‘Pourbaix sensors’: pH and redox-activated fluorescent AND logic gates based on photoinduced electron transfer

Two novel naphthalimide-based ‘Pourbaix sensors’ for redox potential and pH were designed based on a ‘fluorophore–spacer1–receptor–spacer2–electron-donor’ configuration. The synthesised molecular logic gates consist of an alkylated 1,8-naphthalimide fluorophore connected to a tertiary amine by a flexible ethylene spacer to a ferrocene moiety via a methylene spacer. The UV-visible absorption and steady state fluorescent properties were examined in methanol and 1 : 1 (v/v) methanol/water. The spectroscopic properties are modulated by internal charge transfer (ICT) and photoinduced electron transfer (PET) mechanisms. A log βH+ of 9.2 and 8.7 were determined in 1 : 1 (v/v) methanol/water for the methylated 1 and butylated 2 compounds, respectively. An apparent log βFe3+ of 4.2 was determined in 1 : 1 (v/v) methanol/water at pH 4. Time-resolved spectroscopic studies elucidated the stimulus-modulated photoinduced electron transfer pathways. In the oxidised and protonated state, 1 exhibits a single fluorescence lifetime of 8.5 ns, while an efficient photoinduced electron transfer characterised by a time constant of 20 ps is revealed by femtosecond transient absorption spectroscopy in the absence of a perturbing stimulus.

Remote Photoregulated Ring Gliding in a [2]Rotaxane via a Molecular Effector

A molecular barbiturate messenger, which is reversibly released/captured by a photoswitchable artificial molecular receptor, is shown to act as an effector to control ring gliding on a distant hydrogen-bonding [2]rotaxane. Thus, light-driven chemical communication governing the operation of a remote molecular machine is demonstrated using an information-rich neutral molecule.

Efficient oxidation and destabilization of zn(cys)4 zinc fingers by singlet oxygen.

Singlet oxygen ((1)O2) plays an important role in oxidative stress in all types of organisms, most of them being able to mount a defense against this oxidant. Recently, zinc finger proteins have been proposed to be involved in its cellular detection but the molecular basis of this process still remains unknown. We have studied the reactivity of a Zn(Cys)4 zinc finger with (1)O2 by combinations of spectroscopic and analytical techniques, focusing on the products formed and the kinetics of the reaction. We report that the cysteines of this zinc finger are oxidized to sulfinates by (1)O2. The reaction of the ZnS4 core with (1)O2 is very fast and efficient with almost no physical quenching of (1)O2. A drastic (ca. five orders of magnitude) decrease of the Zn(2+) binding constant was observed upon oxidation. This suggests that the Zn(Cys)4 zinc finger proteins would release their Zn(2+) ion and unfold upon reaction with (1)O2 under cellular conditions and that zinc finger sites are likely targets for (1)O2.

[2]Rotaxanes comprising a macrocylic Hamilton receptor obtained using active template synthesis: synthesis and guest complexation

Abstract A macrocyclic ring comprising multiple hydrogen-bonding sites as well as metal-chelating sites is shown to play the role of ligand in active templated, copper-catalysed [2]rotaxane formation via Huisgen and Glaser reactions. The crystallographic structure and copper ion binding studies are provided for the free macrocycle, along with molecular modelling, barbital, N,N′-trimethyleneurea and copper (I) binding information for the new rotaxanes.

Reactivity of a Zn(Cys)2(His)2 Zinc Finger with Singlet Oxygen: Oxidation Directed toward Cysteines but not Histidines

Singlet oxygen ((1)O2) is an important reactive oxygen species in biology that has deleterious effects. Proteins constitute the main target of (1)O2 in cells. Several organisms are able to mount a transcriptional defense against (1)O2. ChrR and MBS are two proteins with Zn(Cys)2(His)2 zinc finger sites that are involved in the regulation of the defense against (1)O2. In this article, we investigate the reactivity of Zn⋅CPF, a Zn(Cys)2(His)2 classical ββα zinc finger, with (1)O2. We show that Zn⋅CPF interacts with (1)O2 mainly by physical quenching using a combination of (1)O2 luminescence quenching and kinetic competition experiments. The chemical reaction, which accounts for 5% of the interaction, leads to oxidation of cysteines but not histidines. Primary photooxidation products, identified by HPLC and mass spectrometry, are sulfinate (75±5%) and disulfides (25±5%). The peptides that have a single cysteine thiolate oxidized into a sulfinate are still able to bind one equivalent Zn(2+) but with a dramatic reduction of the binding constant compared to Zn⋅CPF despite the preservation of the ββα fold, as shown by NMR and CD titrations. Finally, Zn⋅CPF is compared to Zn⋅LTC, a treble clef Zn(Cys)4 zinc finger, to gain further insight into the behavior of zinc fingers toward (1)O2.