Advanced Fluorescent Polymer Probes for the Site-Specific Labeling of Proteins in Live Cells Using the HaloTag Technology.

We report the site-specific and covalent bioconjugation of fluorescent polymer chains to proteins in live cells using the HaloTag technology. Polymer chains bearing a Halo-ligand precisely located at their α-chain-end were synthesized in a controlled manner owing to the RAFT polymerization process. They were labeled in lateral position by several organic fluorophores such as AlexaFluor 647. The resulting Halo-ligand polymer probe was finally shown to selectively recognize and label HaloTag proteins present at the membrane of live cells using confocal fluorescence microscopy. Such a polymer bioconjugation approach holds great promises for various applications ranging from cell imaging to cell surface functionalization.

"Polymultivalent" Polymer-Peptide Cluster Conjugates for an Enhanced Targeting of Cells Expressing αvß3 Integrins.

A new class of "polymultivalent" ligands combining several ligand clusters and a water-soluble biocompatible polymer is introduced. These original conjugates bear two levels of multivalency. They are prepared by covalent coupling of a controlled number of tetrameric cRGD peptide clusters along a well-defined copolymer synthesized by RAFT polymerization. The presence of multiple copies of peptide clusters on the same polymer backbone resulted in a much-higher relative potency than the free cluster reference. Thanks to the "polymultivalency", up to ∼2 orders of magnitude potency enhancement was reached in a competitive cell adhesion assay (nanomolar-range IC50 values). In addition, confocal microscopy and flow cytometry demonstrated that fluorescent "polymultivalent" conjugates (emitting in the far-red/near-infrared region) were able to specifically and selectively label cells expressing αvß3-integrin, the natural receptor of cRGD.

Closer to nature: an ATP-driven bioinspired catalytic oxidation process.

The capability of DNA to acquire enzyme-like properties has led to the emergence of the so-called DNAzyme field; herein, we take a further leap along this nature-inspired road, demonstrating that a template assembled synthetic G-quartet (TASQ) can act as a pre-catalyst for catalytic peroxidase-mimicking oxidation reactions, whatever its nature (guanine or guanosine-based G-quartets), in an ATP-dependent manner, thereby bringing this bioinspired TASQzyme process even closer to nature.