ABSTRACT
The de novo pyrimidine biosynthesis pathway is essential for the proliferation of many pathogens. One of the pathway enzymes, dihydroorotase (DHO), catalyzes the reversible interconversion of N-carbamoyl-l-aspartate to 4,5-dihydroorotate. The substantial difference between bacterial and mammalian DHOs makes it a promising drug target for disrupting bacterial growth and thus an important candidate to evaluate as a response to antimicrobial resistance on a molecular level. Here, we present two novel three-dimensional structures of DHOs from Yersinia pestis (YpDHO), the plague-causing pathogen, and Vibrio cholerae (VcDHO), the causative agent of cholera. The evaluations of these two structures led to an analysis of all available DHO structures and their classification into known DHO types. Comparison of all the DHO active sites containing ligands that are listed in DrugBank was facilitated by a new interactive, structure-comparison and presentation platform. In addition, we examined the genetic context of characterized DHOs, which revealed characteristic patterns for different types of DHOs. We also generated a homology model for DHO from Plasmodium falciparum.
Subject(s)
Dihydroorotase/chemistry , Dihydroorotase/metabolism , Pyrimidines/biosynthesis , Vibrio cholerae/enzymology , Yersinia pestis/enzymology , Amino Acid Sequence , Catalytic Domain , Dihydroorotase/genetics , Genomics , Malates/metabolism , Models, Molecular , Sequence Homology, Amino Acid , Zinc/metabolismABSTRACT
A number of studies were devoted to understanding an immunological effect of pressure-treated ß-lactoglobulin. In our previous work we have proved that high pressure significantly modifies ß-lactoglobulin conformation and consequently its physicochemical properties. Here, structure of ß-lactoglobulin complex with myristic acid determined at the highest accepted by the crystal pressure value of 550â¯MPa is reported. Our results structurally prove that pressure noticeably modifies positions of the major ß-lactoglobulin epitopes. Considering the biological impact of observed changes in epitope regions, high pressure ß-lactoglobulin structure presents a step forward in understanding the pressure modification of food protein allergenicity. The conformational changes of pressurized ß-lactoglobulin did not support the hypothesis that proteolytic digestion facilitated by pressure is caused by an exposure of the digestive sites. Our findings demonstrate that high pressure protein crystallography can potentially identify the most pressure-sensitive fragments in allergens, and can therefore support development of hypoallergenic food products.
Subject(s)
Allergens/immunology , Food Hypersensitivity/etiology , Lactoglobulins/chemistry , Pressure , Epitopes , HumansABSTRACT
Chlorpromazine (CPZ) is a phenothiazine acting as dopamine antagonist. Aside from application in schizophrenia therapy, chlorpromazine is found to be a putative inhibitor of proteins involved in cancers, heritable autism disorder and prion diseases. Four new ß-lactoglobulin variants with double or triple substitutions: I56F/L39A, F105L/L39A, I56F/L39A/M107F or F105L/L39A/M107F changing the shape of the binding pocket were produced and their chlorpromazine binding properties have been investigated by X-ray crystallography, circular dichroism, isothermal titration calorimetry and thermophoresis. The CD spectra and crystal structures revealed that mutations do not affect the protein overall structure but in comparison to WT protein, variants possessing I56F substitution had lower stability while mutation F105L increased melting temperature of the protein. The new variants showed affinity to chlorpromazine in the range 4.2-15.4â¯×â¯103â¯M-1. The CD spectra and crystal structures revealed complementarity of the binding pocket shape, to only one chlorpromazine chiral conformer. The (aR)-CPZ was bonded to variants containing I56F substitution while variants with F105L substitution preferred (aS)-CPZ.