A FLIM Microscopy Based on Acceptor-Detected Förster Resonance Energy Transfer.

Time-resolved donor-detected Förster resonance energy transfer (trDDFRET) allows the observation of molecular interactions of dye-labeled biomolecules in the ∼10-100 Å region. However, we can observe longer-range interactions when using time-resolved acceptor-detected FRET (trADFRET), since the signal/noise ratio can be improved when observing the acceptor emission. Therefore, we propose a new methodology based on trADFRET to construct a new fluorescence lifetime microscopy (FLIM-trADFRET) technique to observe biological machinery in the range of 100-300 Å in vivo, the last frontier in biomolecular medicine.

Dual-Channel Stopped-Flow Apparatus for Simultaneous Fluorescence, Anisotropy, and FRET Kinetic Data Acquisition for Binary and Ternary Biological Complexes.

The Stopped-Flow apparatus (SF) tracks molecular events by mixing the reactants in sub-millisecond regimes. The reaction of intrinsically or extrinsically labeled biomolecules can be monitored by recording the fluorescence, (), anisotropy, (), polarization, (), or FRET, (), traces at nanomolar concentrations. These kinetic measurements are critical to elucidate reaction mechanisms, structural information, and even thermodynamics.

Detailed characterization of the solution kinetics and thermodynamics of biotin, biocytin and HABA binding to avidin and streptavidin.

The high affinity (KD ~ 10-15 M) of biotin for avidin and streptavidin is the essential component in a multitude of bioassays with many experiments using biotin modifications to invoke coupling. Equilibration times suggested for these assays assume that the association rate constant (kon) is approximately diffusion limited (109 M-1s-1) but recent single molecule and surface binding studies indicate that they are slower than expected (105 to 107 M-1s-1). In this study, we asked whether these reactions in solution are diffusion controlled, which reaction model and thermodynamic cycle describes the complex formation, and if there are any functional differences between avidin and streptavidin.

A small molecule directly inhibits the p53 transactivation domain from binding to replication protein A.

Replication protein A (RPA), essential for DNA replication, repair and DNA damage signalling, possesses six ssDNA-binding domains (DBDs), including DBD-F on the N-terminus of the largest subunit, RPA70. This domain functions as a binding site for p53 and other DNA damage and repair proteins that contain amphipathic alpha helical domains. Here, we demonstrate direct binding of both ssDNA and the transactivation domain 2 of p53 (p53TAD2) to DBD-F, as well as DBD-F-directed dsDNA strand separation by RPA, all of which are inhibited by fumaropimaric acid (FPA).

Spectroscopic properties of fluorescein and rhodamine dyes attached to DNA.

We report the spectroscopic properties of fluorescein, x-rhodamine, tetramethyl-rhodamine, attached to single strand, duplex DNA, and to the digestion products by DNAse I. The properties reported include: molar absorptivity, quantum yield, absorbance and fluorescence spectra, fluorescence lifetime, intrinsic lifetime (tau0), static quenching (S) and the Förster critical distances (R0) between fluorescein and x-rhodamine or tetramethyl-rhodamine (acceptors). These spectroscopic properties depend strongly on the local dye environment.

The TATA-binding protein core domain in solution variably bends TATA sequences via a three-step binding mechanism.

Studies of the binding and bending of the AdMLP TATA sequence (TATAAAAG) by the core domain of yeast TBP allow quantitation of the roles of the N-terminal domains of yeast and human TBP. All three proteins bind DNA via a three-step mechanism with no evidence for an initially bound but unbent DNA. The large enthalpy and entropy of activation for the first step in yTBP binding can now be assigned to movement of the NTD from the DNA binding pocket and not to energetics of DNA bending.

TATA-binding protein recognition and bending of a consensus promoter are protein species dependent.

The structure and behavior of full-length human TBP binding the adenovirus major late promoter (AdMLP) have been characterized using biophysical methods. The human protein induces a 97 degrees bend in DNA AdMLP. The high-resolution functional data provide a quantitative energetic and kinetic description of the partial reaction sequence as native human TBP binds rapidly to a consensus promoter with high affinity.

Changes in DNA bending and flexing due to tethered cations detected by fluorescence resonance energy transfer.

Local DNA deformation arises from an interplay among sequence-related base stacking, intrastrand phosphate repulsion, and counterion and water distribution, which is further complicated by the approach and binding of a protein. The role of electrostatics in this complex chemistry was investigated using tethered cationic groups that mimic proximate side chains. A DNA duplex was modified with one or two centrally located deoxyuracils substituted at the 5-position with either a flexible 3-aminopropyl group or a rigid 3-aminopropyn-1-yl group.

Native human TATA-binding protein simultaneously binds and bends promoter DNA without a slow isomerization step or TFIIB requirement.

The association of TATA-binding protein (TBP) with promoter DNA is central to the initiation and regulation of eukaryotic protein synthesis. Our laboratory has previously conducted detailed investigations of this interaction using yeast TBP and seven consensus and variant TATA sequences. We have now investigated this key interaction using human TBP and the TATA sequence from the adenovirus major late promoter (AdMLP).

Reflections on apparent DNA bending by charge variants of bZIP proteins.

Basic-leucine zipper (bZIP) proteins have been studied intensely as transcription factors. It has been proposed that the bZIP domain might modulate transcription activation through the induction of conformational changes in the DNA binding site. We have been interested in using bZIP peptides as convenient models with which to study the role of asymmetric phosphate neutralization in DNA bending.

DNA bending by bZIP charge variants: a unified study using electrophoretic phasing and fluorescence resonance energy transfer.

The role of asymmetric charge neutralization as a primary determinant of protein-induced DNA helical bending remains controversial. Electrophoretic phasing experiments have been conducted previously for peptides derived from the yeast basic leucine zipper (bZIP) transcription factor GCN4 bound to AP-1 sites in duplex DNA. Mutations altering the electrostatic character of amino acids close to the DNA backbone result in phase-dependent gel mobility changes, interpreted as evidence of DNA bending.

Comparison of TATA-binding protein recognition of a variant and consensus DNA promoters.

Assembly of transcription pre-initiation complexes proceeds from the initial complex formed between "TATA" bearing promoter DNA and the TATA-binding protein (TBP). Our laboratory has been investigating the relationships among TATA sequence, TBP center dot TATA solution structure, recognition mechanisms, and transcription efficiency. TBP center dot TATA interactions have been modeled by global analysis of detailed kinetic and thermodynamic data obtained using fluorimetric and fluorometric techniques in conjunction with fluorescence resonance energy transfer.