Munna Sarkar scite author profile

Peptide nucleic acid (PNA) is a DNA analogue in which the negatively charged sugar phosphate backbone has been substituted by uncharged N-(2-aminoethyl)glycine units. The study of a PNA−DNA duplex and the corresponding DNA−DNA duplex gives a unique opportunity to compare two polyelectrolytes with virtually identical geometry but greatly different linear charge density. The results provide a basis for a study of the applicability of the Poisson−Boltzmann (PB) and counterion condensation (CC) theories. UV and circular dichroism spectroscopy as well as isothermal titration calorimetry (ITC) have been used to study the effect of different ions on the stability and conformation of PNA−DNA, PNA−PNA, and DNA−DNA duplexes having the same base sequences. Cations in general destabilize both antiparallel (N/3‘) and parallel (N/5‘) PNA−DNA duplexes whereas they stabilize the DNA−DNA duplex. Studies on the effect of monovalent salt such as NaCl on T m were carried out over a wide range of salt concentrations (0.01 to 5 M). The decrease in the T m of the N/3‘ PNA−DNA duplex with increasing ionic strength in the range of concentrations of 0.01 to 0.5 M, where electrostatic effects predominate, is explained in terms of counterion release upon duplex formation in contrast to the counterion association accompanying the formation of a DNA duplex. The uncharged PNA−PNA duplex shows no significant destabilization in this concentration range. The higher stability of the N/3‘ PNA−DNA compared to the DNA−DNA duplex (ΔΔG ∼ −7 kcal/mol) is ascribed to more favorable entropic contributions consistent with the counterion release that accompanies the PNA−DNA duplex formation. At high salt concentration (>1 M), where electrostatic contributions saturate, similar trends in the decrease in T m were observed for the three types of duplexes irrespective of their backbone charges. The destabilizing effects of a series of Na salts with various monovalent anions on N/3‘ PNA−DNA and PNA−PNA duplexes were found to follow the Hofmeister series, emphasizing the importance of the hydrophobic interaction between nucleobases for the stability of the PNA complexes in high salt concentration.

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Direct binding of Cu(II)-complexes of oxicam NSAIDs with DNA backbone

Roy

Banerjee

Sarkar

2006

Journal of Inorganic Biochemistry

142

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Membrane Fusion Induced by Small Molecules and Ions

Roy

Sarkar

2011

Journal of Lipids

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Membrane fusion is a key event in many biological processes. These processes are controlled by various fusogenic agents of which proteins and peptides from the principal group. The fusion process is characterized by three major steps, namely, inter membrane contact, lipid mixing forming the intermediate step, pore opening and finally mixing of inner contents of the cells/vesicles. These steps are governed by energy barriers, which need to be overcome to complete fusion. Structural reorganization of big molecules like proteins/peptides, supplies the required driving force to overcome the energy barrier of the different intermediate steps. Small molecules/ions do not share this advantage. Hence fusion induced by small molecules/ions is expected to be different from that induced by proteins/peptides. Although several reviews exist on membrane fusion, no recent review is devoted solely to small moleculs/ions induced membrane fusion. Here we intend to present, how a variety of small molecules/ions act as independent fusogens. The detailed mechanism of some are well understood but for many it is still an unanswered question. Clearer understanding of how a particular small molecule can control fusion will open up a vista to use these moleucles instead of proteins/peptides to induce fusion both in vivo and in vitro fusion processes.

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Munna Sarkar

A library of IR bands of nucleic acids in solution

Ionic Effects on the Stability and Conformation of Peptide Nucleic Acid Complexes

Direct binding of Cu(II)-complexes of oxicam NSAIDs with DNA backbone

Membrane Fusion Induced by Small Molecules and Ions

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