Debasis Saha scite author profile

Transmembrane anion transport modality is enjoying a renewed interest because of recent advances toward anticancer therapy. Here we show bis(sulfonamides) as efficient receptors for selective Cl(-) ion binding and transport across lipid bilayer membranes. Anion-binding studies by (1)H NMR indicate a logical correlation between the acidity of sulfonamide N-H proton and binding strength. Such recognition is influenced further by the lipophilicity of a receptor during the ion-transport process. The anion-binding and transport activity of a bis(sulfonamide) system are far superior compared to those of the corresponding bis(carboxylic amide) derivative. Fluorescent-based assays confirm the Cl(-)/anion antiport as the operational mechanism of the ion transport by bis(sulfonamides). Disruption of ionic homeostasis by the transported Cl(-) ion, via bis(sulfonamide), is found to impose cell death. Induction of a caspase-dependent intrinsic pathway of apoptosis is confirmed by monitoring the changes in mitrochondrial membrane potential, cytochrome c leakage, activation of family of caspases, and nuclear fragmentation studies.

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An Ultrahydrophobic Fluorous Metal–Organic Framework Derived Recyclable Composite as a Promising Platform to Tackle Marine Oil Spills

Mukherjee

Kansara

Saha

et al. 2016

Chemistry A European J

106

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Derived from a strategically chosen hexafluorinated dicarboxylate linker aimed at the designed synthesis of a superhydrophobic metal-organic framework (MOF), the fluorine-rich nanospace of a water-stable MOF (UHMOF-100) exhibits excellent water-repellent features. It registered the highest water contact angle (≈176°) in the MOF domain, marking the first example of an ultrahydrophobic MOF. Various experimental and theoretical studies reinforce its distinctive water-repellent characteristics, and the conjugation of superoleophilicity and unparalleled hydrophobicity of a MOF material has been coherently exploited to achieve real-time oil/water separation in recyclable membrane form, with significant absorption capacity performance. This is also the first report of an oil/water separating fluorinated ultrahydrophobic MOF-based membrane material, with potential promise for tackling marine oil spillages.

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Distribution of Residence Time of Water around DNA Base Pairs: Governing Factors and the Origin of Heterogeneity

2015

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Water dynamics in the solvation shell around biomolecules plays a vital role in their stability, function, and recognition processes. Although extensively studied through various experimental and computational methods, dynamical time scales of water near DNA is highly debated. The residence time of water is one such dynamical quantity that has been probed rarely around DNA using computational methods. Moreover, the effect of local DNA sequence variation in water residence time has also not been addressed. Using 20 DNA systems with different sequences, we capture here the mean residence time (MRT) of water molecules around 360 different sites in the major and minor grooves of DNA. Thus, we show that a distribution of time scales exists even for a regular structure of DNA, reflecting the effect of chemistry, topography, and other factors governing dynamics of water. We used the stable state picture (SSP) formalism to calculate MRT that avoids the effect of transient recrossing. Results obtained from simulations agree well with experiments done on a few specific systems at a similar temperature. Most importantly, we find that although the groove width and depth influence water time scale, MRT of water is always longer in the middle of the DNA, in agreement with NMR experiments. We propose a simple kinetic model of water escape from DNA where water molecules move along the DNA and perpendicular to it in both the first and second solvation shell before it escapes to bulk. We show that this simple kinetic model captures both the time scale and the position dependence of MRT of water around DNA. This study thus portrays the origin and a measure of heterogeneity in water dynamics around DNA and provides a fresh perspective in the ongoing debate on water dynamical time scales around DNA.

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Effect of water and ionic liquids on biomolecules

Saha

Mukherjee

2018

Biophys Rev

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The remarkable progress in the field of ionic liquids (ILs) in the last two decades has involved investigations on different aspects of ILs in various conditions. The nontoxic and biocompatible nature of ILs makes them a suitable substance for the storage and application of biomolecules. In this regard, the aqueous IL solutions have attracted a large number of studies to comprehend the role of water in modulating various properties of biomolecules. Here, we review some of the recent studies on aqueous ILs that concern the role of water in altering the behavior of ILs in general and in case of biomolecules solvated in ILs. The different structural and dynamic effects caused by water have been highlighted. We discuss the different modes of IL interaction that are responsible for stabilization and destabilization of proteins and enzymes followed by examples of water effect on this. The role of water in the case of nucleic acid storage in ILs, an area which has mostly been underrated, also has been emphasized. Our discussions highlight the fact that the effects of water on IL behavior are not general and are highly dependent on the nature of the IL under consideration. Overall, we aim to draw attention to the significance of water dynamics in the aqueous IL solutions, a better understanding of which can help in developing superior storage materials for application purposes.

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Impact of Ions on Individual Water Entropy

Saha

Mukherjee

2016

J. Phys. Chem. B

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Solutes determine the properties of a solution. In this study, we probe ionic solutions through the entropy of individual water molecules in the solvation shells around different cations and anions. Using a method recently developed by our group, we show the solvation shell entropy stemming from the individual contributions correlates extremely well with experimental values for both polarizable and nonpolarizable force fields. The behavior of water entropy as a function of distance reveals significant (∼20%) contributions from the second solvation shell even for the low concentration considered here. While for the cations, contributions from both translational and rotational entropy loss are similar in different solvation shells, water around anions loses much more rotational entropy due to their ability to accept hydrogen bonds. Most importantly, while charge density of cations or anions correlates with the translational entropy loss, anions with similar charge density as that of cations has a much stronger and long-range effect on water. We also show how the modulation of water entropy by ions is correlated to the structural modifications of hydration shell. This study thus provides a step toward understanding the entropic behavior of water in molecular recognition processes between proteins and drug molecules.

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Debasis Saha

Chloride-Mediated Apoptosis-Inducing Activity of Bis(sulfonamide) Anionophores

An Ultrahydrophobic Fluorous Metal–Organic Framework Derived Recyclable Composite as a Promising Platform to Tackle Marine Oil Spills

Distribution of Residence Time of Water around DNA Base Pairs: Governing Factors and the Origin of Heterogeneity

Effect of water and ionic liquids on biomolecules

Impact of Ions on Individual Water Entropy

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