FRET and LRET Biosensors for Cell-based Imaging and Screening of Rac1 Activation

Rac1 is a key regulator of several cell signaling pathways and dysregulated Rac1 activation has been implicated in cancer. Genetically encoded Forster resonance energy transfer (FRET) biosensors with enhanced dynamic range enabled live cell fluorescence imaging of Rac1 activity and a cell lysate-based assay of Rac1 inhibition in 96-well plates. We prepared HEK293T cell lines that stably expressed polypeptides with a general domain sequence (N- to C-terminus) of 1) FRET acceptor; 2) Rac/Cdc42 binding domain of human p21 protein kinase A (residues 68-150); 3) a linker domain; 4) FRET donor; and 5) full-length Rac1. Activated Rac1 binds to the protein kinase A domain, bringing donors and acceptors close together to increase FRET. We evaluated the effects on FRET signal dynamic range of alpha helical linkers comprised of alternating repeats of roughly four glutamate and four arginine or lysine residues. So-called ER/K linkers had limited effects on conventional FRET biosensors that incorporated the fluorescent protein (FP) pairs mCerulean/YPet, or mTFP1(cp227)/mVenus(cp229). Fluorometric measurements of cells that co-expresssed biosensors with positive (TIAM1) or negative (RhoGDI) Rac1 regulators revealed significant dynamic range enhancement in only one FP construct (mCerulean/YPet with 20 nm ER/K linker) relative to an analogous structure that incorporated an unstructured linker. We transfected this construct into a cell line that stably expressed a rapamycin-inducible c-Src analog (RapR-Src) and observed activation of Rac1 at protruding edges following rapamycin stimulation. In cells that expressed lanthanide-based FRET (LRET biosensors) that incorporated a luminescent terbium complex donor and GFP fluorescent acceptor, time-gated luminescence (TGL) measurements showed substantial gains in dynamic range that increased with linker length (up to 1200%). We robustly detected small molecule Rac1 inhibition following lysis of LRET biosensor-expressing cells grown directly in 96-well plates. The results herein highlight the potential of FRET and LRET biosensors with ER/K linkers for cell-based imaging and screening of protein activities.

Thermal and Emission Properties of a Series of Lanthanides Complexes with N-Biphenyl-Alkylated-4-Pyridone Ligands: Crystal Structure of a Terbium Complex with N-Benzyl-4-Pyridone

This work focuses on the investigation of the liquid crystalline behavior and luminescence properties of the lanthanide complexes of Eu(III), Sm(III) and Tb(III) with N-biphenyl-alkylated-4-pyridone ligands. The organic ligands having a biphenyl group attached via a long flexible spacer with either 9 or 10 carbon atoms were synthesized by the reaction between 4-hydroxypyridine and the corresponding bromide compounds. The chemical structures of the organic and lanthanide complexes were assigned based on elemental analysis, single-crystal X-ray diffraction, 1H, 13C NMR and IR spectroscopies, and thermogravimetric analysis (TGA). The X-ray diffraction analysis of a parent compound shows that the lanthanide ions are surrounded by three monodentate pyridone ligands and three bidentate nitrate ions, giving a 9-coordinate environment. The mesogenic behavior and the type of liquid crystalline phases exhibited by the new complexes were analyzed by differential scanning calorimetry (DSC) and polarizing optical microscopy (POM), and powder X-ray diffraction (XRD) studies. Only the lanthanide complexes with longer spacer (10) display a monotropic SmA phase, typically on a short thermal range (less than 10 °C). The complexes with shorter flexible chains (9) show no liquid crystalline properties with melting temperatures lower than their analogs with longer spacers. The emission spectra recorded in solid state at room temperatures show typical emission bands for each lanthanide ion employed (Eu(III), Tb(III) and Sm(III)).

Ten-Coordinate Lanthanide [Ln(HL)(L)] Complexes (Ln = Dy, Ho, Er, Tb) with Pentadentate N3O2-Type Schiff-Base Ligands: Synthesis, Structure and Magnetism

A series of five neutral mononuclear lanthanide complexes [Ln(HL)(L)] (Ln = Dy3+, Ho3+ Er3+ and Tb3+) with rigid pentadentate N3O2-type Schiff base ligands, H2LH (1-Dy, 3-Ho, 4-Er and 6-Tb complexes) or H2LOCH3, (2-Dy complex) has been synthesized by reaction of two equivalents of 1,1′-(pyridine-2,6-diyl)bis(ethan-1-yl-1-ylidene))dibenzohydrazine (H2LH, [H2DAPBH]) or 1,1′-(pyridine-2,6-diyl)bis(ethan-1-yl-1-ylidene))di-4-methoxybenzohydrazine (H2LOCH3, [H2DAPMBH]) with common lanthanide salts. The terbium complex [Tb(LH)(NO3)(H2O)2](DME)2 (5-Tb) with one ligand H2LH was also obtained and characterized. Single crystal X-ray analysis shows that complexes 1–4 have the composition {[Ln3+(HL)−(L)2−] solv} and similar molecular structures. In all the compounds, the central Ln3+ ion is chelated by two interlocked pentadentate ligands resulting in the coordination number of ten. Each lanthanide ion is coordinated by six nitrogen atoms and four oxygen atoms of the two N3O2 chelating groups forming together a distorted bicapped square antiprismatic polyhedron N6O4 with two capping pyridyl N atoms in the apical positions. The ac magnetic measurements reveal field-induced single-molecule magnet (SMM) behavior of the two dysprosium complexes (with barriers of Ueff = 29 K at 800 Oe in 1-Dy and Ueff = 70 K at 300 Oe in 2-Dy) and erbium complex (Ueff = 87 K at 1500 Oe in 4-Er); complex 3-Ho with a non-Kramers Ho3+ ion is SMM-silent. Although 2-Dy differs from 1-Dy only by a distant methoxy-group in the phenyl ring of the ligand, their dynamic magnetic properties are markedly different. This feature can be due to the difference in long-range contributions (beyond the first coordination sphere) to the crystal-field (CF) potential of 4f electrons of Dy3+ ion that affects magnetic characteristics of the ground and excited CF states. Magnetic behavior and the electronic structure of Ln3+ ions of 1–4 complexes are analyzed in terms of CF calculations.