Your search keyword '"Brzezinski K"' showing total 3 results

1. Right-handed Z-DNA at ultrahigh resolution: a tale of two hands and the power of the crystallographic method.

Author

Drozdzal P, Manszewski T, Gilski M, Brzezinski K, and Jaskolski M

Subjects

Nucleic Acid Conformation, Models, Molecular, X-Ray Diffraction, Water, DNA, Z-Form

Abstract

The self-complementary L-d(CGCGCG) 2 purine/pyrimidine hexanucleotide was crystallized in complex with the polyamine cadaverine and potassium cations. Since the oligonucleotide contained the enantiomeric 2'-deoxy-L-ribose, the Z-DNA duplex is right-handed, as confirmed by the ultrahigh-resolution crystal structure determined at 0.69 Å resolution. Although the X-ray diffraction data were collected at a very short wavelength (0.7085 Å), where the anomalous signal of the P and K atoms is very weak, the signal was sufficiently outstanding to clearly indicate the wrong hand when the structure was mistakenly solved assuming the presence of 2'-deoxy-D-ribose. The electron density clearly shows the entire cadaverinium dication, which has an occupancy of 0.53 and interacts with one Z-DNA duplex. The K + cation, with an occupancy of 0.32, has an irregular coordination sphere that is formed by three OP atoms of two symmetry-related Z-DNA duplexes and one O5' hydroxyl O atom, and is completed by three water sites, one of which is twofold disordered. The K + site is complemented by a partial water molecule, the hydrogen bonds of which have the same lengths as the K-O bonds. The sugar-phosphate backbone assumes two conformations, but the base pairs do not show any sign of disorder., (open access.)

Published

2023

2. Biochemical and structural insights into an unusual, alkali-metal-independent S-adenosyl-L-homocysteine hydrolase from Synechocystis sp. PCC 6803.

Author

Malecki PH, Imiolczyk B, Barciszewski J, Czyrko-Horczak J, Sliwiak J, Gawel M, Wozniak K, Jaskolski M, and Brzezinski K

Subjects

Bacterial Proteins chemistry, Bacterial Proteins metabolism, Catalysis, Rubidium, S-Adenosylmethionine metabolism, Hydrolases chemistry, Hydrolases metabolism, Synechocystis chemistry, Synechocystis metabolism

Abstract

The mesophilic cyanobacterium Synechocystis sp. PCC 6803 encodes an S-adenosyl-L-homocysteine hydrolase (SAHase) of archaeal origin in its genome. SAHases are essential enzymes involved in the regulation of cellular S-adenosyl-L-methionine (SAM)-dependent methylation reactions. They are usually active as homotetramers or, less commonly, as homodimers. A SAHase subunit is composed of two major domains: a cofactor (NAD + )-binding domain and a substrate (S-adenosyl-L-homocysteine)-binding domain. These are connected by a hinge element that is also a coordination site for an alkali-metal cation that influences domain movement during the catalytic cycle. Typically, the highest activity and strongest substrate binding of bacterial SAHases are observed in the presence of K + ions. The SAHase from Synechocystis (SynSAHase) is an exception in this respect. Enzymatic and isothermal titration calorimetry studies demonstrated that in contrast to K + -dependent SAHases, the activity and ligand binding of SynSAHase are not affected by the presence of any particular alkali ion. Moreover, in contrast to other SAHases, the cyanobacterial enzyme is in an equilibrium of two distinct oligomeric states corresponding to its dimeric and tetrameric forms in solution. To explain these phenomena, crystal structures of SynSAHase were determined for the enzyme crystallized in the presence of adenosine (a reaction byproduct or substrate) and sodium or rubidium cations. The structural data confirm that while SynSAHase shares common structural features with other SAHases, no alkali metal is coordinated by the cyanobacterial enzyme as a result of a different organization of the macromolecular environment of the site that is normally supposed to coordinate the metal cation. This inspired the generation of SynSAHase mutants that bind alkali-metal cations analogously to K + -dependent SAHases, as confirmed by crystallographic studies. Structural comparisons of the crystal structure of SynSAHase with other experimental models of SAHases suggest a possible explanation for the occurrence of the cyanobacterial enzyme in the tetrameric state. On the other hand, the reason for the existence of SynSAHase in the dimeric state in solution remains elusive.

Published

2022

3. Structural and biophysical studies of new L-asparaginase variants: lessons from random mutagenesis of the prototypic Escherichia coli Ntn-amidohydrolase.

Author

Loch JI, Klonecka A, Kądziołka K, Bonarek P, Barciszewski J, Imiolczyk B, Brzezinski K, Gilski M, and Jaskolski M

Subjects

Models, Molecular, Mutagenesis, Mutation, Asparaginase chemistry, Escherichia coli

Abstract

This work reports the results of random mutagenesis of the Escherichia coli class 2 L-asparaginase EcAIII belonging to the Ntn-hydrolase family. New variants of EcAIII were studied using structural, biophysical and bioinformatic methods. Activity tests revealed that the L-asparaginase activity is abolished in all analyzed mutants with the absence of Arg207, but some of them retained the ability to undergo the autoproteolytic maturation process. The results of spectroscopic studies and the determined crystal structures showed that the EcAIII fold is flexible enough to accept different types of mutations; however, these mutations may have a diverse impact on the thermal stability of the protein. The conclusions from the experiments are grouped into six lessons focused on (i) the adaptation of the EcAIII fold to new substitutions, (ii) the role of Arg207 in EcAIII activity, (iii) a network of residues necessary for autoprocessing, (iv) the complexity of the autoprocessing reaction, (v) the conformational changes observed in enzymatically inactive variants and (vi) the cooperativity of the EcAIII dimer subunits. Additionally, the structural requirements (pre-maturation checkpoints) that are necessary for the initiation of the autocleavage of Ntn-hydrolases have been classified. The findings reported in this work provide useful hints that should be considered before planning enzyme-engineering experiments aimed at the design of proteins for therapeutic applications. This is especially important for L-asparaginases that can be utilized in leukemia therapy, as alternative therapeutics are urgently needed to circumvent the severe side effects associated with the currently used enzymes., (open access.)

Published

2022