Detection of protein–DNA interactions in crude cellular extracts by fluorescence correlation spectroscopy

Analytical Form of the Fluorescence Correlation Spectroscopy Autocorrelation Function in Chemically Reactive Systems

Fluorescence correlation spectroscopy (FCS) applied to chemically reactive systems provides information about chemical reaction equilibrium constants and diffusion coefficients of reactants. These physical quantities are determined from the FCS-measured autocorrelation function, G(t), as a function of time, t. In most of the studied cases, the analytical form of G(t) is well-known for reactions that are much faster than the diffusion time of reactants across the focal volume probed by FCS or when they are much slower than the diffusion time. Here, we develop an analytical form of G(t) for reactions occurring at an intermediate time scale comparable to the diffusion time. G(t) depends on the reaction rates in such reactions. We focus on reversibly binding a fluorescently labeled small molecule to a macromolecule in a diluted solution in thermodynamic equilibrium. Our approach allows the analysis of FCS data over a wide range of diffusion coefficients, reaction rate constants, and brightness levels of fluorescent labels. Our G(t) is valid even when the fluorescent label changes its brightness upon binding. The easy-to-implement analytical form of the autocorrelation function greatly helps experimentalists study chemical reactions, determining the equilibrium constants of reactions and the reaction rates.

Heterogeneous Dynamical Environment at the Interface of a Protein-DNA Complex

Binding between protein and DNA is an essential process to regulate different biological activities. Two puzzling questions in protein-DNA recognition are (i) how the protein's binding domain identifies the DNA sequence in an aqueous solution and (ii) how the formation of the complex alters the dynamical environment around it. In this work, we present results obtained from molecular dynamics simulations of the N-terminal α-helical domain of the λ-repressor protein (in dimeric form) bound to the corresponding operator DNA. Effects of formation of the complex in modifying the microscopic dynamics of water as well as the kinetics of hydrogen bonds at the interface have been explored. Locally heterogeneous restricted water motions at the complex interface have been observed, the extent of restriction being more significant around the directly bound residues of the protein and the DNA. In particular, the calculation revealed the existence of significantly constrained motionally restricted water layer that can form either bridges around the directly bound residues of the protein and DNA or are engaged in forming water-mediated contacts between a fraction of the unbound residues. More importantly, it is observed that the restricted water motion around the complex is correlated with the hydrogen bond relaxation time scale at the interface. It is further demonstrated that the kinetics of water-water hydrogen bonds involving the bridged water are influenced more due to complex formation.

Flexibility of the Binding Regions of a Protein-DNA Complex and the Structure and Ordering of Interfacial Water

Noncovalent interactions between protein and DNA are important to comprehend different biological activities in living organisms. One important issue is how the protein identifies the target DNA and the influence of the resulting protein-DNA complex on the hydration environment around it. In this study, we have carried out atomistic molecular dynamics simulations of the protein-DNA complex formed by the dimeric form of the α-helical N-terminal domain of the λ-repressor protein with its operator DNA. Local heterogeneous flexibilities of the residues of the protein and the DNA components that are involved in binding and the microscopic structure and ordering of water around those have been investigated in detail. The calculations revealed concurrent existence of highly ordered as well as disordered water molecules at the interface. It is found that a fraction of doubly coordinated water molecules exhibit high degree of ordering at the interface, while the randomly oriented ones are coordinated with three water molecules. The effect has been found to be more around the protein and DNA residues that are in contact in the complexed state. We believe that such highly ordered two-coordinated water molecules are likely to act as an adhesive to facilitate the formation of a protein-DNA complex and maintain its structural stability.

Affinity-based high-resolution analysis of DNA binding by VASCULAR-RELATED NAC-DOMAIN7 via fluorescence correlation spectroscopy

VASCULAR-RELATED NAC-DOMAIN7 (VND7) is the master transcription factor for vessel element differentiation in Arabidopsis thaliana. To identify the cis-acting sequence(s) bound by VND7, we employed fluorescence correlation spectroscopy (FCS) to find VND7-DNA interactions quantitatively. This identified an 18-bp sequence from the promoter of XYLEM CYSTEINE PEPTIDASE1 (XCP1), a direct target of VND7. A quantitative assay for binding affinity between VND7 and the 18-bp sequence revealed the core nucleotides contributing to specific binding between VND7 and the 18-bp sequence. Moreover, by combining the systematic evolution of ligands by exponential enrichment (SELEX) technique with known consensus sequences, we defined a motif termed the Ideal Core Structure for binding by VND7 (ICSV). We also used FCS to search for VND7 binding sequences in the promoter regions of other direct targets. Taking these data together, we proposed that VND7 preferentially binds to the ICSV sequence. Additionally, we found that substitutions among the core nucleotides affected transcriptional regulation by VND7 in vivo, indicating that the core nucleotides contribute to vessel-element-specific gene expression. Furthermore, our results demonstrate that FCS is a powerful tool for unveiling the DNA-binding properties of transcription factors.

Fluorescence correlation spectroscopy study of the complexation of DNA hybrids, IgG antibody, and a chimeric protein of IgG-binding ZZ domains fused with a carbohydrate binding module

Fluorescence correlation spectroscopy (FCS) was used to characterize the molecular interactions between the four components of a DNA recognition system.

Microscopic understanding of the conformational features of a protein–DNA complex

Protein–DNA interactions play crucial roles in different stages of genetic activities, such as replication of genome, initiation of transcription,etc.

A rapid and high-throughput quantitation assay of the nuclear factor κB activity using fluorescence correlation spectroscopy in the setting of clinical laboratories

Background

Transcription factor nuclear factor-κB (NF-κB) plays a key role in the regulation of immune responses to inflammation. However, convenient assay systems to quantitate the NF-κB activity level in a timely manner are not available in the setting of clinical laboratories. Therefore, we developed a novel and high-throughput quantitative assay based on fluorescence correlation spectroscopy (FCS) to detect the NF-κB activity level in cellular nuclear extracts and evaluated the performance of this method. The basic principle of this assay is to calculate the binding fraction of NF-κB to fluorescent-labeled DNA probes, which contain NF-κB binding sites.

Methods

Non-fluorescent competitive probes are employed to normalize the influence of the viscosity of the nuclear extracts between samples and to eliminate the influence of nonspecific binding of the fluorescent probes. To confirm accurate quantitation, human recombinant NF-κB p50 was mixed into U937 cell nuclear extracts, and the binding fraction of the fluorescent probes to NF-κB in the mixture was calculated for quantitation. To evaluate whether this method can be applied to measure the NF-κB activity in human lymphocytes, the NF-κB activity levels of systemic inflammatory response syndrome patients during perioperative periods were measured.

Results

The percentage recovery was 88.9%. The coefficients of variation of the intra-assay were approximately 10%. NF-κB activity levels during the perioperative period can were successfully measured. The assay time for the FCS measurement was within 20 minutes.

Conclusions

This assay system can be used to quantitate NF-κB activity levels in a timely manner in the setting of hospital laboratories.

Mitochondrial transcription factors TFAM and TFB2M regulate Serca2 gene transcription

AIMS

Sarco(endo)plasmic reticulum Ca²(+)-ATPase 2a (SERCA2a) transports Ca²(+) by consuming ATP produced by mitochondrial respiratory chain enzymes. Messenger RNA (mRNA) for these enzymes is transcribed by mitochondrial transcription factors A (TFAM) and B2 (TFB2M). This study examined whether TFAM and TFB2M coordinately regulate the transcription of the Serca2 gene and mitochondrial genes.

METHODS AND RESULTS

Nuclear localization of TFAM and TFB2M was demonstrated by immunostaining in rat neonatal cardiac myocytes. Chromatin immunoprecipitation assay and fluorescence correlation spectroscopy revealed that TFAM and TFB2M bind to the -122 to -114 nt and -122 to -117 nt regions of the rat Serca2 gene promoter, respectively. Mutation of these sites resulted in decreased Serca2 gene transcription. In a rat myocardial infarction model, Serca2a mRNA levels significantly correlated with those of Tfam (r = 0.54, P < 0.001) and Tfb2m (r = 0.73, P < 0.001). Overexpression of TFAM and TFB2M blocked hydrogen peroxide- and norepinephrine-induced decreases in Serca2a mRNA levels. In addition, overexpression of TFAM and TFB2M increased the mitochondrial DNA (mtDNA) copy number and mRNA levels of mitochondrial enzymes.

CONCLUSION

Although TFAM and TFB2M are recognized as mtDNA-specific transcription factors, they also regulate transcription of nuclear DNA, i.e. the Serca2 gene. Our findings suggest a novel paradigm in which the transcription of genes for mitochondrial enzymes that produce ATP and the gene for SERCA2a that consumes ATP is coordinately regulated by the same transcription factors. This mechanism may contribute to maintaining proper cardiac function.

A new small molecule that directly inhibits the DNA binding of NF-kappaB

Nuclear factor-kappaB (NF-kappaB) has been considered as a good target for the treatment of many diseases. Although a lot of NF-kappaB inhibitors have already been reported, many of them have several common problems. Thus, we attempted to identify novel NF-kappaB inhibitors to be unique lead compounds for creating new pharmaceuticals. In the present study, we screened our chemical library for compounds that directly inhibit the DNA binding of NF-kappaB by using fluorescence correlation spectroscopy (FCS). Consequently, we identified a promising compound, 4,6-dichloro-N-phenyl-1,3,5-triazin-2-amine, referred to as NI241. It mediated a dose-dependent inhibition of the DNA binding of NF-kappaB p50. Its analogues also showed dose-dependent inhibition and their inhibitory effects were altered by the substituents on the N-phenyl group. Furthermore, we predicted the binding mode of NI241 with p50 in silico. In this model, NI241 forms three hydrogen bonds with Tyr60, His144, and Asp242 on p50, which are important amino acid residues for the interaction with DNA. These results suggest that NI241 with structural novelty may serve as a useful scaffold for the creation of new NF-kappaB inhibitors by rational optimization.

Self-assembled cationic nanogels for intracellular protein delivery

An effective intracellular protein delivery system with self-assembled cationic nanogels is reported. Interaction of proteins with self-assembled nanogels of cationic cholesteryl group-bearing pullulans (CHPNH 2) was investigated by dynamic light scattering (DLS), transmission electron micrograph (TEM), fluorescence resonance energy transfer (FRET), and fluorescence correlation spectroscopy (FCS). The cationic nanogels strongly interacted with bovine serum albumin (BSA) and formed monodispersed nanoparticels (<50 nm). The complex more effectively internalized into HeLa cells than cationic liposomes and a protein transduction domain (PTD) based carrier even in the presence of serum. The higher efficiency of the nanogel carrier is probably due to the formation of colloidally stable nanoparticles with the protein. The enzymatic activity of beta-galactosidase (beta-Gal) was retained after internalization into cells. The nanogel carrier promoted nuclear delivery of a GFP-conjugated nuclear localization signal and Tat as a PTD (Tat-NLS-GFP). A blocking experiment with chemical inhibitors revealed the possible involvement of macropinocytosis in the uptake of the nanogel complex. After cellular uptake, the complex of the nanogel-protein was dissociated and the protein was released inside the cell. Such a self-assembled cationic nanogel system should create opportunities for novel applications of protein delivery.

Detection of weak ligand interactions of leukocyte Ig-like receptor B1 by fluorescence correlation spectroscopy

Fluorescence correlation spectroscopy (FCS) can directly and quickly detect the translational diffusion of individual fluorescence-labeled molecules in solutions. Although FCS analyses for protein-protein interactions have been performed, the very weak interactions generally observed in cell-cell recognition of the immune system have not been examined in detail. Here, we report the FCS analysis for low-affinity and fast-kinetic binding (K(d) greater than muM range) of the human inhibitory immune cell surface receptor, leukocyte immunoglobulin-like receptor B1 (LILRB1), to its ligands, MHC (major histocompatibility complex) class I molecules (MHCIs) by using the single-molecule FCS detection system which requires only a small amount of sample. Since the random labeling technique for LILRB1 disturbed the MHCI binding, we performed site-specific labeling of LILRB1 by introducing a cysteine residue at the C-terminus, which could be covalently attached with the fluorescence reagent, Alexa647. This technique can be applied to other type I membrane receptors. The low-affinity binding of LILRB1-Alexa647 to MHCIs (HLA-Cw4, and -G1) was detected by FCS, even though non-labeled MHCIs were only twice as big as the labeled LILRB1. Their dissociation constants (7.5 muM (HLA-Cw4) and 5.7 muM (HLA-G1)) could be determined and were consistent with surface plasmon resonance (SPR) data. These results indicate that the single-molecule FCS detection system is capable of analyzing the binding characteristics of immune cell surface receptors even in difficult cases such as (1) small amount of protein samples, (2) small difference in molecular weight and (3) weak affinity. Therefore, it is a powerful tool for characterization and high throughput inhibitor screening of a wide variety of cell-cell recognition receptors involved in immunologically relevant events.

Monitoring the interaction between DNA and a transcription factor (MEF2A) using fluorescence correlation spectroscopy

Fluorescence correlation spectroscopy (FCS) is an analytical method that allows distinguishing different populations of fluorescent probes in solution and provides data on their concentrations and their diffusion coefficients. FCS was used to characterize the interaction of the transcription factor (MEF2A) with its DNA target sequence. The myocyte enhancer factor 2 (MEF2) belongs to the MADS-box family and activates transcription of numerous muscle genes during myogenesis. Measurements were made using TAMRA-labelled oligonucleotide duplexes derived from a wild type (WT) or a mutated MEF2 target gene. Binding of the protein to the WT DNA resulted in significant changes of the diffusion. Specificity of the interaction was confirmed using the mutated DNA. Bound to free probe ratios were determined at different MEF2A concentrations and the apparent equilibrium dissociation constant K(D) for the full-length MEF2A was estimated.