Strukturní a funkční studie vybraných mutantů haloalkan dehalogenasy DhaA

Structural biology is one of the most quickly growing fields of research in life sciences. X-ray diffraction analysis is the technique that allows direct visualization of protein structure at the atomic or near-atomic level. Structure solution of proteins and protein complexes by X-ray crystallography provides important insights into their mode of action. The haloalkane dehalogenase proteins represent objects of interest for protein engineering studies, attempting to improve their catalytic efficiency or broaden their substrate specificity towards environmental pollutants. In the present study, the structures of three haloalkane dehalogenase DhaA mutants DhaA04, DhaA14 and DhaA15 at atomic resolution are reported and compared to explore the effect of mutations on the enzymatic activity of modified proteins from a structural perspective. Besides that, in this work, the crystallization and initial X-ray diffraction characterization of DhaA wild type and its mutant variant DhaA13 in complex with environmental pollutant 1,2,3-trichloropropane and the crystallization of DhaA13 in complex with the fluorescence dye coumarin are described

Crystal structure of ErmE-23S rRNA methyltransferase in macrolide resistance

Pathogens often receive antibiotic resistance genes through horizontal gene transfer from bacteria that produce natural antibiotics. ErmE is a methyltransferase (MTase) from Saccharopolyspora erythraea that dimethylates A2058 in 23S rRNA using S-adenosyl methionine (SAM) as methyl donor, protecting the ribosomes from macrolide binding. To gain insights into the mechanism of macrolide resistance, the crystal structure of ErmE was determined to 1.75 Å resolution. ErmE consists of an N-terminal Rossmann-like α/ß catalytic domain and a C-terminal helical domain. Comparison with ErmC' that despite only 24% sequence identity has the same function, reveals highly similar catalytic domains. Accordingly, superposition with the catalytic domain of ErmC' in complex with SAM suggests that the cofactor binding site is conserved. The two structures mainly differ in the C-terminal domain, which in ErmE contains a longer loop harboring an additional 310 helix that interacts with the catalytic domain to stabilize the tertiary structure. Notably, ErmE also differs from ErmC' by having long disordered extensions at its N- and C-termini. A C-terminal disordered region rich in arginine and glycine is also a present in two other MTases, PikR1 and PikR2, which share about 30% sequence identity with ErmE and methylate the same nucleotide in 23S rRNA

Product formation controlled by substrate dynamics in leukotriene A4 hydrolase.

Leukotriene A4 hydrolase/aminopeptidase (LTA4H) (EC 3.3.2.6) is a bifunctional zinc metalloenzyme with both an epoxide hydrolase and an aminopeptidase activity. LTA4H from the African claw toad, Xenopus laevis (xlLTA4H) has been shown to, unlike the human enzyme, convert LTA4 to two enzymatic metabolites, LTB4 and another biologically active product Δ(6)-trans-Δ(8)-cis-LTB4 (5(S),12R-dihydroxy-6,10-trans-8,14-cis-eicosatetraenoic acid). In order to study the molecular aspect of the formation of this product we have characterized the structure and function of xlLTA4H. We solved the structure of xlLTA4H to a resolution of 2.3Å. It is a dimeric structure where each monomer has three domains with the active site in between the domains, similar as to the human structure. An important difference between the human and amphibian enzyme is the phenylalanine to tyrosine exchange at position 375. Our studies show that mutating F375 in xlLTA4H to tyrosine abolishes the formation of the LTB4 isomeric product Δ(6)-trans-Δ(8)-cis-LTB4. In an attempt to understand how one amino acid exchange leads to a new product profile as seen in the xlLTA4H, we performed a conformer analysis of the triene part of the substrate LTA4. Our results show that the Boltzmann distribution of substrate conformers correlates with the observed distribution of products. We suggest that the observed difference in product profile between the human and the xlLTA4H arises from different level of discrimination between substrate LTA4 conformers

Structure of the decoy module of human glycoprotein 2 and uromodulin and its interaction with bacterial adhesin FimH

Glycoprotein 2 (GP2) and uromodulin (UMOD) filaments protect against gastrointestinal and urinary tract infections by acting as decoys for bacterial fimbrial lectin FimH. By combining AlphaFold2 predictions with X-ray crystallography and cryo-EM, we show that these proteins contain a bipartite decoy module whose new fold presents the high-mannose glycan recognized by FimH. The structure rationalizes UMOD mutations associated with kidney diseases and visualizes a key epitope implicated in cast nephropathy.Ministry of Health (MOH)National Medical Research Council (NMRC)Published versionThis work was supported by the Swedish Research Council (project grants 2016-03999 and 2020-04936 to L.J.), the Karolinska Institutet Research Foundation (grant 2016fobi50035 to L.J.), the Knut and Alice Wallenberg Foundation (project grant 2018.0042 to L.J.) and the Ministry of Health, Singapore, NMRC grant (MOH-000382-00 to B.W.). Open access funding provided by Karolinska Institute