Bidisha Sengupta

Base-Directed Formation of Fluorescent Silver Clusters

Small silver clusters that form with short oligonucleotides are distinguished by their strong fluorescence. Previous work showed that red and blue/green emitting species form with the cytosine oligonucleotide dC12. To understand how the bases and base sequence influence cluster formation, the blue/green emitting clusters that form with the thymine-containing oligonucleotides dT12, dT4C4T4, and dC4T4C4 are discussed. With dT12 and dT4C4T4, variations in the solution pH establish that the clusters associate with the N3 of thymine. The small clusters are bound to the larger DNA template, as demonstrated by fluorescence anisotropy, circular dichroism, and fluorescence correlation spectroscopy (FCS) studies. For dT4C4T4, FCS studies showed that approximately 50% of the strands are labeled with the fluorescent clusters. Absorption spectra and the gas dependence of the fluorescence show that nonfluorescent clusters also form following the reduction of the silver cation - oligonucleotide conjugates. Fluorescent cluster formation is favored by oxygen, thus indicating that the DNA-bound clusters are partially oxidized. To elaborate the sequence dependence of cluster formation, dC4T4C4 was studied. Cluster formation depends on the oligonucleotide concentration, and higher concentrations favor a red emitting species. A blue/green emissive species dominates at lower concentrations of dC4T4C4, and it has spectroscopic, physical, and chemical properties that are similar to those of the clusters that form with dT12 and dT4C4T4. These results suggest that cytosine- and thymine-containing oligonucleotides stabilize a preferred emissive silver cluster.

Optically enhanced, near-IR, silver cluster emission altered by single base changes in the DNA template.

Few-atom silver clusters harbored by DNA are promising fluorophores due to their high molecular brightness along with their long- and short-term photostability. Furthermore, their emission rate can be enhanced when co-illuminated with low-energy light that optically depopulates the fluorescence-limiting dark state. The photophysical basis for this effect is evaluated for two near-infrared-emitting clusters. Clusters emitting at ∼800 nm form with C(3)AC(3)AC(3)TC(3)A and C(3)AC(3)AC(3)GC(3)A, and both exhibit a trap state with λ(max) ∼ 840 nm and an absorption cross section of (5-6) × 10(-16) cm(2)/molecule that can be optically depopulated. Transient absorption spectra, complemented by fluorescence correlation spectroscopy studies, show that the dark state has an inherent lifetime of 3-4 μs and that absorption from this state is accompanied by photoinduced crossover back to the emissive manifold of states with an action cross section of ∼2 × 10(-18) cm(2)/molecule. Relative to C(3)AC(3)AC(3)TC(3)A, C(3)AC(3)AC(3)GC(3)A produces a longer-lived trap state and permits more facile passage back to the emissive manifold. With the C(3)AC(3)AC(3)AC(3)G template, a spectrally distinct cluster forms having emission at ∼900 nm, and its trap state has a ∼4-fold shorter lifetime. These studies of optically gated fluorescence bolster the critical role of the nucleobases in both the formation and excited state dynamics of these highly emissive metallic clusters.

DNA sensing by amplifying the number of near-infrared emitting, oligonucleotide-encapsulated silver clusters.

A bifunctional oligonucleotide integrates in situ synthesis of a fluorogenic silver cluster with recognition of a target DNA sequence. With the template C(3)AC(3)AC(3)GC(3)A, a complex forms with 10 silver atoms that possesses electronic transitions in the near-infrared and that is detected at nanomolar concentrations using diode laser excitation. Pendant to this cluster encoding region, the recognition component binds a target DNA strand through hybridization, and decoupling of these two regions of the composite sensor renders a modular sensor for specific oligonucleotides. A target is detected using a quencher strand that bridges the cluster template and recognition components and disturbs cluster binding, as indicated by static quenching. Competitive displacement of the quencher by the target strand restores the favored cluster environment, and our key finding is that this exchange enhances emission through a proportional increase in the number of emissive clusters. DNA detection is also accomplished in serum-containing buffers by taking advantage of the high brightness of this fluorophore and the inherently low endogenous background in the near-infrared spectral region. Cluster stability in this biological environment is enhanced by supplementing the solutions with Ag(+).

Optical sensing by transforming chromophoric silver clusters in DNA nanoreactors

Bifunctional DNA oligonucleotides serve as templates for chromophoric silver clusters and as recognition sites for target DNA strands, and communication between these two components is the basis of an oligonucleotide sensor. Few-atom silver clusters exhibit distinct electronic spectra spanning the visible and near-infrared region, and they are selectively synthesized by varying the base sequence of the DNA template. In these studies, a 16-base cluster template is adjoined with a 12-base sequence complementary to the target analyte, and hybridization induces structural changes in the composite sensor that direct the conversion between two spectrally and stoichiometrically distinct clusters. Without its complement, the sensor strand selectively harbors ~7 Ag atoms that absorb at 400 nm and fold the DNA host. Upon association of the target with its recognition site, the sensor strand opens to expose the cluster template that has the binding site for ~11 Ag atoms, and absorption at 720 nm with relatively strong emission develops in lieu of the violet absorption. Variations in the length and composition of the recognition site and the cluster template indicate that these types of dual-component sensors provide a general platform for near-infrared-based detection of oligonucleotides in challenging biological environments.

Structural studies of a trinucleotide repeat sequence using 2-aminopurine

The secondary structure of repeated trinucleotide sequences results in the development of several neurodegenerative diseases, and these studies consider the (CAG)(8) sequence that forms a stem-loop hairpin. The structural and thermodynamic properties of this hairpin are assessed using 2-aminopurine substitutions for adenine at six positions in this repeated sequence. Circular dichroism spectra and thermal denaturation experiments show that the secondary structure is not disturbed by the modifications. The local structure of the hairpin was monitored using the fluorescence intensities of 2-aminopurines, the changes in the intensity relative to the denatured state, and the sensitivity of the fluorescence to quenching by acrylamide. To establish the stem and loop characteristics in (CAG)(8), known reference points for stem, loop, and exposed base motifs were used. In the vicinity of the loop, the bases become more solvent exposed, which suggests that the instability associated with this repeated hairpin influences the global secondary structure. These results provide the basis to interpret the structures adopted by other repeated (CAG) structures.

Context Dependence of Trinucleotide Repeat Structures

Long repeated sequences of DNA and their associated secondary structure govern the development and severity of a significant class of neurological diseases. Utilizing the effect of base stacking on fluorescence quantum yield, 2-aminopurine substitutions for adenine previously demonstrated sequestered bases in the stem and exposed bases in the loop for an isolated (CAG)(8) sequence. This study evaluates (CAG)(8) that is incorporated into a duplex, as this three-way junction is a relevant model for intermediates that lead to repeat expansion during DNA replication and repair. From an energetic perspective, thermally induced denaturation indicates that the duplex arms dictate stability and that the secondary structure of the repeated sequence is disrupted. Substitutions with 2-aminopurine probe base exposure throughout this structure, and two conclusions about secondary structure are derived. First, the central region of (CAG)(8) is more solvent-exposed than single-stranded DNA, which suggests that hairpin formation in the repeated sequence is disrupted. Second, base stacking becomes compromised in the transition from the duplex to (CAG)(8), resulting in bases that are most similar to single-stranded DNA at the junction. Thus, an open (CAG)(8) loop and exposed bases in the arms indicate that the strand junction profoundly influences repeated sequences within three-way junctions.

An assessment of the usefulness of 5-hydroxytryptophan as an optical probe

Abstract 5-Hydroxytryptophan (5HT) has been the focus of much recent attention as a novel intrinsic fluorescence probe for proteins. Solvent-dependence studies reported here show that, compared to other fluorophores of related interest like tryptophan (Trp) and 7-azatryptophan (7AT), the fluorescence emission maximum (λemmax) of 5HT is relatively insensitive to solvent polarity. Thus, upon change of solvent from acetonitrile to water, the λemmax of 5HT fluorescence is red shifted by only 3 nm, in contrast to corresponding red shifts of much larger magnitudes observed for Trp and 7AT (14 and 23 nm, respectively). This behaviour suggests the lack of significant solvent dipolar relaxation effects in 5HT, which is corroborated by the low temperature emission measurements at 77°K. This aspect is also revealed in the fluorescence characteristics of 5HT in a membrane-mimetic model system, namely in AOT reverse-micellar assemblies containing different amounts of water. With increase in water content, the λemmax of 5HT remains almost unaffected, although fluorescence anisotropy and quenching data clearly indicate significant changes in the microenvironments of 5HT molecules.

5-Hydroxyindole: usefulness as a novel optical probe

Abstract Some years ago the non-natural amino acid 5-hydroxytryptophan (5HT) was proposed as a novel intrinsic fluorescence probe for protein structure, function and dynamics. In this connection, 5-hydroxyindole (5HI) merits particular attention, since it is the chromophoric moiety of 5HT. In our previous reports it was shown that unlike other well-known fluorescence probes, the fluorescence emission maximum ( λ em max ) of the 5HI chromophore is insensitive to environment. Here we demonstrate the potential utility of 5HI as an extrinsic optical probe for biological systems (such as membranes and proteins), exploiting its fluorescence anisotropy ( r ) as a useful parameter. Small, unilamellar liposomal membranes of synthetic phosphatidylcholine, (DPPC) and the protein bovine serum albumin (BSA) were chosen as testing grounds. Our studies reveal that the anisotropy ( r ) of 5HI serves as an excellent monitor for estimating the gel to liquid crystalline phase transition temperature ( T m ) of the phospholipid, as well as protein binding characteristics (binding constant and Gibbs free energy). Implications of these results are discussed.

Excited State Proton Transfer of Natural Flavonoids and Their Chromophores in Duplex and Tetraplex DNAs

Fisetin (3,7,3′,4′-tetrahydroxyflavone) and quercetin (3,5,7,3′,4′-pentahydroxyflavone) are the bioactive plant flavonoids that are potentially useful therapeutic drugs for the treatment of a broad spectrum of diseases, including atherosclerosis, cardiovascular disease, obesity, hypertension, and cancer. 3-Hydroxyflavone (3HF) and 7-hydroxyflavone (7HF) are the synthetic chromophores of fisetin and quercetin. We have exploited dual luminescence properties of fisetin and quercetin along with 3-HF and 7HF to examine their efficacy of binding and compare their interactions with DNA, which is one of the macromolecular targets of flavonoids in physiological systems. Following the sequence of the human telomeric DNA 5′-d (CCCTAA-)n/(-TTAGGG)n-5′, two single-stranded DNA oligonucleotides, 5′-d(C3TA2)3C3-3′ and 5′-d(T2AG3)4-3′, and their duplex were used as receptors to study binding by the ligands quercetin, fisetin, and their chromophores. Circular dichroism, differential absorption, UV thermal melting, and size exclusion chromatographic studies indicated the formation of unusual DNA structures (such as C4 and G4 tetraplexes) for both the C- and G-rich single-stranded DNAs. Upon binding to DNA, dramatic changes were observed in the intrinsic fluorescence behavior of the flavonoids. Molecular docking studies were performed to describe the likely binding sites for the ligands. The spectroscopic studies on flavonoid–DNA interactions described herein demonstrate a powerful approach for examining their DNA binding through exploiting the highly sensitive intrinsic fluorescence properties of the flavonoids as their own “reporter” for their interactions with macromolecular targets.

Differential roles of 3-Hydroxyflavone and 7-Hydroxyflavone against nicotine-induced oxidative stress in rat renal proximal tubule cells

Plant flavonoids are well known as antioxidants against oxidative stress induced by exposure to external pollutants. Nicotine (NIC) is one of those agents which increases renal oxidative stress, an important factor in the pathogenesis of renal epithelial injury in smokers. Although several studies had been conducted on flavonoids and oxidative stress, the mechanism of the protective pathways are not fully understood. Here, we present studies on antioxidant properties of two mono-hydroxyflavone isomers, 3-hydroxyflanove (3HF)- and 7-hydroxyflavone (7HF), against nicotine-associated oxidative stress and injury in cultured renal proximal tubule cells and correlate their antioxidant properties with their chemical structure. Our data clearly demonstrates, for the first time, that while both 3HF and 7HF protect renal cells from NIC-associated cytotoxicity, the mechanism of their action is different: 3HF elicits protective activity via the PKA/CREB/MnSOD pathway while 7HF does so via the ERK/Nrf2/HO-1 pathway. Molecular docking and dynamics simulations with two major signaling pathway proteins showed significant differences in the binding energies of 3HF (-5.67 and -7.39 kcal.mol-1) compared to 7HF (-5.41 and -8.55 kcal.mol-1) in the matrices of CREB and Keap1-Nrf2 proteins respectively, which corroborate with the observed differences in their protective properties in the renal cells. The implications of this novel explorative study is likely to promote the understanding of the mechanisms of the antioxidative functions of different flavones.