WT_all.txt

Leu124 collar aperture in wild-type KirBac3.

Hexyl_all.txt

Leu124 collar dimensions with C199 mutant hexyl-disulfid

Decyl_all.txt

Dimensions of Leu124 collar aperture with C119 mutant decyl-disulfid

Initial Complexed Molecular Dynamics Structures

Initial Complexed Molecular Dynamics Structures</p

Final Complexed Molecular Dynamics Gromacs Structures

Final Complexed Molecular Dynamics Gromacs Structures</p

Final Monomeric Molecular Dynamics Gromacs Structures

Final Monomeric Molecular Dynamics Gromacs Structures</p

Initial Monomeric Molecular Dynamics Structures

Initial Monomeric Molecular Dynamics Structures</p

Predicting aqueous solubility by QSPR modeling

The aqueous solubility is predicted here using quantitative structure property relationship (QSPR) models. In this study, we examine whether descriptors that individually yield favorable models for the prediction of the Gibbs energy of solvation and sublimation can be used in combination with octanol-water partition coefficient to produce QSPR models for the prediction of aqueous solubility. Based on this strategy, applied to seven distinct datasets, all models exhibited an R2 greater than 0.7 and Q2 greater than 0.6 for the estimation of aqueous solubility. We also determined how uncoupling the descriptors used to create QSPR models in the prediction of Gibbs energy of sublimation yielded an improved model. Model refinement using an artificial neural network applying the same descriptors generated significantly better models with improved R2 and standard deviation.</p

BioPPSy: An Open-Source Platform for QSAR/QSPR Analysis

The reliability of quantitative structure-property relationship (QSPR) and quantitative structure-activity relationship (QSAR) models is often difficult to assess due to the problems of accessing the tools and data used to build the models. We present here BioPPSy, which aims to fill this gap by providing an easy-to-use open-source software platform. We demonstrate the program capabilities by calculating three key properties used in drug discovery, aqueous solubility, Caco-2 cell permeability and blood-brain barrier permeability. A comparison is made with a number of previously reported methods, taken from the literature, for each property. </p

Structure of the Plasmodium falciparum PfSERA5 pseudo-zymogen

PfSERA5, a significantly abundant protein present within the parasitophorous vacuole (PV) and essential for normal growth during the blood-stage life cycle of the malaria parasite Plasmodium falciparum, displays structural similarity to many other cysteine proteases. However, PfSERA5 does not exhibit any detectable protease activity and therefore the role of the PfSERA5 papain-like domain (PfSERA5E), thought to remain bound to its cognate prodomain, remains unknown. In this study, we present a revised structure of the central PfSERA5E domain at a resolution of 1.2 Å, and the first structure of the “zymogen” of this papain-like domain including its cognate prodomain (PfSERA5PE) to 2.2 Å resolution. PfSERA5PE is somewhat structurally similar to that of other known proenzymes, retaining the conserved overall folding and orientation of the prodomain through, and occluding, the archetypal papain-like catalytic triad “active-site” cleft, in the same reverse direction as conventional prodomains. Our findings are congruent with previously identified structures of PfSERA5E and of similar “zymogens” and provide a foundation for further investigation into the function of PfSERA5.</p