Masa-aki Inoue

The first fluorescent chemosensors toward a native phosphorylated peptide are successfully synthesized. Dinuclear zinc(II)-dipicolylamine-based anthracene (1, 2) can selectively recognize and sense phosphorylated species with an increase in the fluorescence intensity. We also demonstrated that these artificial receptors fluorometrically detect a phosphorylated peptide with high affinity (>107 M-1) in aqueous solution.

We have developed a new fluorescent binuclear Zn(II) complex for the detection of neurofibrillary tangles (NFTs) of hyperphosphorylated tau proteins, a representative hallmark of Alzheimer's disease (AD). The probe 1 incorporates a fluorescent BODIPY unit and two Zn(II)-2,2'-dipicolylamine (Dpa) complexes as a binding site for phosphorylated amino acid residues. Using fluorescence titration to evaluate the binding and sensing properties of 1 toward several phosphorylated peptide segments derived from hyperphosphorylated tau protein, we found that 1 binds preferentially to peptides presenting phosphorylated groups at the i and i+4 positions with dissociation constants (K(d)) in the micromolar range. Fluorescence titration with an artificially prepared aggregate of the phosphorylated tau protein (p-Tau) revealed that 1 binds strongly to p-Tau (EC(50) = 9 nM). In contrast, the interactions of 1 were weaker toward artificially prepared aggregates of the nonphosphorylated tau protein (n-Tau; EC(50) = 80 nM) and Abeta(1-42) fibrils (EC(50) = 650 nM). Histological imaging of a hippocampus tissue section obtained from an AD patient revealed that 1 fluorescently visualizes deposits of NFTs and clearly discriminates between NFTs and the amyloid plaques assembled from amyloid-beta peptides, confirming our strategy toward the rational design of a molecular probe for the selective fluorescence detection of NFTs in brain tissue sections.

In the research field of molecular recognition, selective recognition and sensing of phosphorylated protein surfaces is strongly desirable both for elucidation of protein-protein recognition at the molecular level and for regulation of signal transduction through protein surfaces. Here we describe a new strategy for molecular recognition of a multi-phosphorylated peptide using intrapeptide cross-linking on the basis of coordination chemistry. The present artificial receptor can selectively bind to doubly phosphorylated peptide through multiple-point interactions and fluorescently sense the binding event with an association constant of more than 106 M-1 in neutral aqueous solution.

Protein phosphorylation is ubiquitously involved in living cells, and it is one of the key events controlling protein−protein surface interactions, which are essential in signal transduction cascades. We now report that the small molecular receptors bearing binuclear Zn(II)-Dpa can strongly bind to a bis-phosphorylated peptide in a cross-linking manner under neutral aqueous conditions when the distance between the two Zn(II) centers can appropriately fit in that of the two phosphate groups of the phosphorylated peptide. The binding property was quantitatively determined by ITC (isothermal titration calorimetry), induced CD (circular dichroism), and NMR. On the basis of these findings, we demonstrated that these types of small molecules were able to effectively disrupt the phosphoprotein−protein interaction in a phosphorylated CTD peptide and the Pin1 WW domain, a phosphoprotein binding domain, at a micromolar level. The strategy based on a small molecular disruptor that directly interacts with phosphoprotein is unique and should be promising in developing a designer inhibitor for phosphoprotein−protein interaction.

This paper describes a new fluorescent chemosensor for phosphorylated peptide, which comprises a rigid trans-4,4'-diazastilbene and two Zn(II)-Dpa (2,2'-dipicolylamine) units; this chemosensor sequence-selectively binds to a (i, i + 1) bis-phosphorylated peptide and displays a dual-emission fluorescence change.