Your search keyword '"Laishram R"' showing total 4 results

1. Living with urea stress

Author

Singh, Laishram R., Dar, Tanveer Ali, and Ahmad, Faizan

Published

2009

2. Relationship between functional activity and protein stability in the presence of all classes of stabilizing osmolytes.

Author

Jamal, Shazia, Poddar, Nitesh K., Singh, Laishram R., Dar, Tanveer A., Rishi, Vikas, and Ahmad, Faizan

Subjects

ORGANIC compounds, AMINO acids, CARBON compounds, HYDROGEN-ion concentration, POLYOLS

Abstract

We report the effects of stabilizing osmolytes (low molecular mass organic compounds that raise the midpoint of thermal denaturation) on the stability and function of RNase-A under physiological conditions (pH 6.0 and 25 °C). Measurements of Gibbs free energy change at 25 °C (Δ GD°) and kinetic parameters, Michaelis constant ( Km) and catalytic constant ( kcat) of the enzyme mediated hydrolysis of cytidine monophosphate, enabled us to classify stabilizing osmolytes into three different classes based on their effects on kinetic parameters and protein stability. (a) Polyhydric alcohols and amino acids and their derivatives do not have significant effects on Δ GD° and functional activity ( Km and kcat). (b) Methylamines increase Δ GD° and kcat, but decrease Km. (c) Sugars increase Δ GD°, but decrease both Km and kcat. These findings suggest that, among the stabilizing osmolytes, (a) polyols, amino acids and amino acid derivatives are compatible solutes in terms of both stability and function, (b) methylamines are the best refolders (stabilizers), and (c) sugar osmolytes stabilize the protein, but they apparently do not yield functionally active folded molecules. [ABSTRACT FROM AUTHOR]

Published

2009

3. Structural-functional integrity of lysozyme in imidazolium based surface active ionic liquids.

Author

Rather, Mudasir Ahmad, Dar, Tanveer Ali, Singh, Laishram R., Rather, Ghulam Mohammad, and Bhat, Mohsin Ahmad

Subjects

*LYSOZYMES, *IONIC liquids, *THERMAL stability, *INTEGRITY, *PROTEIN stability

Abstract

The present study was designed to explore the hydrophobicity and concentration dependence of imidazolium based surface active ionic liquids (SAILs) effects on the structural-functional integrity of proteins. Specifically, we investigated the impact of SAILs viz. 1-octyl-3-methylimidazolium dodecylbenzenesulfonate ([OMIM][DBS]) and 1-dodecyl-3-methylimidazolium dodecylbenzenesulfonate ([DDMIM][DBS]) on activity, structure and stability of lysozyme. Activity measurements revealed that, in contrast to [DDMIM][DBS] that renders lysozyme either feebly active or inactive, [OMIM][DBS] significantly enhances the lysozyme activity in the concentration range of critical aggregation concentrations (CAC) to C s (SAIL saturation concentration of protein backbone) i.e., 0.5 mM–1.35 mM. Tensiometric results in agreement with turbidity measurements inferred significant composition and concentration dependence of the lysozyme-SAIL interactions. Spectroscopic investigations revealed that compared to destabilizing behaviour of [DDMIM][DBS], [OMIM][DBS] significantly enhances both conformational as well as thermal stability of lysozyme in the CAC to C s concentration regime. Altogether, results obtained do indicate that [OMIM][DBS], in the concentration regime of CAC to C s , serves as an efficient stabiliser with an ability to appreciably enhance the activity, thermal stability and overall conformational stability of lysozyme. We firmly believe that [OMIM][DBS], at least in the CAC to C s concentration ranges, can be exploited as a promising stabiliser and activity enhancer for numerous industrially important enzymes. [ABSTRACT FROM AUTHOR]

Published

2020

4. A current perspective on the compensatory effects of urea and methylamine on protein stability and function.

Author

Rahman, Safikur, Warepam, Marina, Singh, Laishram R., and Dar, Tanveer Ali

Subjects

*METHYLAMINES, *PROTEIN stability, *UREA, *DENATURATION of proteins, *BIOACCUMULATION, *MACROMOLECULES

Abstract

Urea is a strong denaturant and inhibits many enzymes but is accumulated intracellularly at very high concentrations (up to 3–4 M) in mammalian kidney and in many marine fishes. It is known that the harmful effects of urea on the macromolecular structure and function is offset by the accumulation of an osmolytic agent called methylamine. Intracellular concentration of urea to methylamines falls in the ratio of 2:1 to 3:2 (molar ratio). At this ratio, the thermodynamic effects of urea and methylamines on protein stability and function are believed to be algebraically additive. The mechanism of urea-methylamine counteraction has been widely investigated on various approaches including, thermodynamic, structural and functional aspects. Recent advances have also revealed atomic level insights of counteraction and various molecular dynamic simulation studies have yielded significant molecular level informations on the interaction between urea and methylamines with proteins. It is worthwhile that urea-methylamine system not only plays pivotal role for the survival and functioning of the renal medullary cells but also is a key osmoregulatory component of the marine elasmobranchs, holocephalans and coelacanths. Therefore, it is important to combine all discoveries and discuss the developments in context to physiology of the mammalian kidney and adaptation of the marine organisms. In this article we have for the first time reviewed all major developments on urea-counteraction systems to date. We have also discussed about other additional urea-counteraction systems discovered so far including urea-NaCl, urea-myoinsoitol and urea-molecular chaperone systems. Insights for the possible future research have also been highlighted. [ABSTRACT FROM AUTHOR]

Published

2015