Interatomic potentials and solvation parameters from protein engineering data for buried residues

Van der Waals (vdW) interaction energies between different atom types, energies of hydrogen bonds (H‐bonds), and atomic solvation parameters (ASPs) have been derived from the published thermodynamic stabilities of 106 mutants with available crystal structures by use of an originally designed model for the calculation of free‐energy differences. The set of mutants included substitutions of uncharged, inflexible, water‐inaccessible residues in α‐helices and β‐sheets of T4, human, and hen lysozymes and HI ribonuclease. The determined energies of vdW interactions and H‐bonds were smaller than in molecular mechanics and followed the “like dissolves like” rule, as expected in condensed media but not in vacuum. The depths of modified Lennard‐Jones potentials were −0.34, −0.12, and −0.06 kcal/mole for similar atom types (polar–polar, aromatic–aromatic, and aliphatic–aliphatic interactions, respectively) and −0.10, −0.08, −0.06, −0.02, and nearly 0 kcal/mole for different types (sulfur–polar, sulfur–aromatic, sulfur–aliphatic, aliphatic–aromatic, and carbon–polar, respectively), whereas the depths of H‐bond potentials were −1.5 to −1.8 kcal/mole. The obtained solvation parameters, that is, transfer energies from water to the protein interior, were 19, 7, −1, −21, and −66 cal/moleÅ 2 for aliphatic carbon, aromatic carbon, sulfur, nitrogen, and oxygen, respectively, which is close to the cyclohexane scale for aliphatic and aromatic groups but intermediate between octanol and cyclohexane for others. An analysis of additional replacements at the water–protein interface indicates that vdW interactions between protein atoms are reduced when they occur across water.Peer Reviewedhttp://deepblue.lib.umich.edu/bitstream/2027.42/106915/1/111984_ftp.pd

Structural studies of a thermostable citrate synthase

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MYCOBACTERIOPHAGE LYSINS: BIOINFORMATIC CHARACTERIZATION OF LYSIN A AND IDENTIFICATION OF THE FUNCTION OF LYSIN B IN INFECTION

Tuberculosis kills nearly 2 million people each year, and more than one-third of the world�s population is infected with the causative agent, Mycobacterium tuberculosis. Mycobacteriophages, or bacteriophages that infect Mycobacterium species including M. tuberculosis, are already being used as tools to study mycobacteria and diagnose tuberculosis. More than 60 mycobacteriophage genomes have been sequenced, revealing a vast genetic reservoir containing elements useful to the study and manipulation of mycobacteria. Mycobacteriophages also encode proteins capable of fast and efficient killing of the host cell. In most bacteriophages, lysis of the host cell to release progeny phage requires at minimum two proteins: a holin that mediates the timing of lysis and permeabilizes the cell membrane, and an endolysin (lysin) that degrades peptidoglycan. Accessory lysis proteins have also been discovered, often with functions specific to that phage�s host.Many lysins of phages infecting Gram-positive bacteria are proving to be potent antibacterials. Further, lysis proteins can provide insight into the properties and composition of the host cell wall. Given the complexity of the mycobacterial cell wall and its medical relevance in tuberculosis as an immunogenic barrier that complicates treatment, as well as the urgent need for new therapeutic options, the mycobacteriophage lysins clearly warrant further scientific investigation.This work focuses on the mycobacteriophage lysin LysA and the accessory lysis protein LysB. Bioinformatic characterizations show that LysA proteins posess a variety of domains arranged in modular organizations, reflecting extensive recombination within the mycobacteriophage population. In addition to known peptidoglycan-hydrolytic activities, novel cell wall-binding domains are identified, as well as several domains of unknown function found only in mycobacteriophages. LysB proteins are unique to mycobacteriophages and perform a singular role as mycolylarabinogalactan esterases that sever the connection between the mycobacterial outer membrane and the peptidoglycan cell wall complex to ensure efficient lysis and progeny phage release. There is also preliminary evidence of peptidoglycan hydrolytic ability, inducible cell lysis, and growth inhibition of Mycobacterium smegmatis by LysA and LysB proteins. These studies suggest that mycobacteriophage lysis proteins can be exploited as useful tools, both in the laboratory and clinical setting