Mitochondrial membrane model: Lipids, elastic properties, and the changing curvature of cardiolipin.

Mammalian and Drosophila melanogaster model mitochondrial membrane compositions are constructed from experimental data. Simplified compositions for inner and outer mitochondrial membranes are provided, including an asymmetric inner mitochondrial membrane. We performed atomistic molecular dynamics simulations of these membranes and computed their material properties. When comparing these properties to those obtained by extrapolation from their constituting lipids, we find good overall agreement. Finally, we analyzed the curvature effect of cardiolipin, considering ion concentration effects, oxidation, and pH. We draw the conclusion that cardiolipin-negative curvature is most likely due to counterion effects, such as cation adsorption, in particular of H3O+. This oft-neglected effect might account for the puzzling behavior of this lipid.

Molecular dynamics analyses of CLDN15 pore size and charge selectivity.

The Claudin-15 (CLDN15) channel is important for nutrient, electrolyte, and water transport in the gastrointestinal tract. We used cell culture studies and molecular dynamics simulations to elucidate its structure and permeability mechanisms. We provide a model that underscores the crucial role of the D55 residue in the CLDN15 selectivity filter, which interacts with permeating cations. Our studies demonstrated the mechanisms whereby the size and charge of the D55 residue influence paracellular permeability. By altering D55 to larger, negatively charged glutamic acid (E) or similarly sized neutral asparagine (N), we observed changes in pore size and selectivity, respectively. D55E mutation decreased pore size, favoring small ion permeability without affecting charge selectivity, while D55N mutation led to reduced charge selectivity without markedly altering size selectivity. These findings shed light on the complex interplay of size and charge selectivity of CLDN15 channels. This knowledge can inform the development of strategies to modulate the function of CLDN15 and similar channels, which has implications for tight junction modulation in health and disease.

Probing the dynamics between the substrate and the product towards glucose tolerance of Halothermothrix orenii ß-glucosidase.

Most ß-Glucosidase (B8CYA8) are prone to inhibition by glucose. Experimentally observed specific activity of B8CYA8 on 20 mM, 50 mM, and 100 mM p-nitrophenyl-ß-D-glucopyranoside (pNPGlc) substrate concentrations show surprise dependence on the presence of 0-3 M glucose at 335 K. We found that at high substrate concentration, the enzyme shows stimulation in specific activity with glucose and the glucose inhibition curve shifts toward the right with the increase in the substrate concentration. We employed atomistic molecular dynamics simulations of ß-Glucosidase from Halothermothrix orenii at different glucose and pNPGlc concentrations to provide microscopic explanations to the experimentally observed non-monotonic glucose concentration dependence of the enzyme activity. Our results show that accumulation of substrate (pNPGlc) near the B8CYA8 catalytic site residues E166 and E354 and in the active site tunnel increases up to 0.5 M glucose when the specific activity is the highest. The number of pNPGlc in the tunnel decreases drastically when glucose concentration is more than 0.5 M, and hence the specific activity decreases. Potential of mean force (PMF) calculations showed that the most favorable interaction between pNPGlc and ß-Glucosidase exists at 0.5 M glucose while at deficient and high glucose concentrations, the binding energy between the substrate and ß-Glucosidase is very low. These studies provide the molecular basis towards understanding inhibition and stimulation of ß-Glucosidase activity in the presence of glucose and may enable the optimum use of enzymes for the efficient conversion of high biomass loading saccharification reactions.Communicated by Ramaswamy H. Sarma.

Elucidating the regulation of glucose tolerance in a ß-glucosidase from Halothermothrix orenii by active site pocket engineering and computational analysis.

ß-Glucosidase catalyzes the hydrolysis of ß-1,4 linkage between two glucose molecules in cello-oligosaccharides and is prone to inhibition by the reaction product glucose. Relieving the glucose inhibition of ß-glucosidase is a significant challenge. Towards the goal of understanding how glucose interacts with ß-glucosidase, we expressed in Escherichia coli, the Hore_15280 gene encoding a ß-glucosidase in Halothermothrix orenii. Our results show that the enzyme is glucose tolerant, and its activity on p-nitrophenyl D-glucopyranoside stimulated in the presence of up to 0.5 M glucose. NMR analyses show the unexpected interactions between glucose and the ß-glucosidase at lower concentrations of glucose that, however, does not lead to enzyme inhibition. We identified non-conserved residues at the aglycone-binding and the gatekeeper site and show that increased hydrophobicity at the pocket entrance and a reduction in steric hindrances are critical towards enhanced substrate accessibility and significant improvement in activity. Analysis of structures and in combination with molecular dynamics simulations show that glucose increases the accessibility of the substrate by enhancing the structural flexibility of the active site pocket and may explain the stimulation in specific activity up to 0.5 M glucose. Such novel regulation of ß-glucosidase activity by its reaction product may offer novel ways of engineering glucose tolerance.

Probing the Effect of Glucose on the Activity and Stability of ß-Glucosidase: An All-Atom Molecular Dynamics Simulation Investigation.

ß-Glucosidase (EC 3.2.1.21) plays an essential role in the removal of glycosyl residues from disaccharide cellobiose to produce glucose during the hydrolysis of lignocellulosic biomass. Although there exist a few ß-glucosidase that are tolerant to large concentrations of glucose, these enzymes are typically prone to glucose inhibition. Understanding the basis of this inhibition is important for the production of cheaper biofuels from lignocellulose. In this study, all-atom molecular dynamics simulation at different temperatures and glucose concentrations was used to understand the molecular basis of glucose inhibition of GH1 ß-glucosidase (B8CYA8) from Halothermothrix orenii. Our results show that glucose induces a broadening of the active site tunnel through residues lining the tunnel and facilitates the accumulation of glucose. In particular, we observed that glucose accumulates at the tunnel entrance and near the catalytic sites to block substrate accessibility and inhibit enzyme activity. The reduction of enzyme activity was also confirmed experimentally through specific activity measurements in the presence of 0-2.5 M glucose. We also show that the increase in glucose concentrations leads to a decrease in the number of water molecules inside the tunnel to affect substrate hydrolysis. Overall, the results help in understanding the role of residues along the active site tunnel for the engineering of glucose-tolerant ß-glucosidase.

Molecular switching behavior in isosteric DNA base pairs.

The structures and proton-coupled behavior of adenine-thymine (A-T) and a modified base pair containing a thymine isostere, adenine-difluorotoluene (A-F), are studied in different solvents by dispersion-corrected density functional theory. The stability of the canonical Watson-Crick base pair and the mismatched pair in various solvents with low and high dielectric constants is analyzed. It is demonstrated that A-F base pairing is favored in solvents with low dielectric constant. The stabilization and conformational changes induced by protonation are also analyzed for the natural as well as the mismatched base pair. DNA sequences capable of changing their sequence conformation on protonation are used in the construction of pH-based molecular switches. An acidic medium has a profound influence in stabilizing the isostere base pair. Such a large gain in stability on protonation leads to an interesting pH-controlled molecular switch, which can be incorporated in a natural DNA tract.