Andrej Perdih scite author profile

Bacterial DNA gyrase is a well-established and validated target for the development of novel antibacterials. Starting from the available structural information about the binding of the natural product inhibitor, clorobiocin, we identified a novel series of 4'-methyl-N(2)-phenyl-[4,5'-bithiazole]-2,2'-diamine inhibitors of gyrase B with a low micromolar inhibitory activity by implementing a two-step structure-based design procedure. This novel class of DNA gyrase inhibitors was extensively investigated by various techniques (differential scanning fluorimetry, surface plasmon resonance, and microscale thermophoresis). The binding mode of the potent inhibitor 18 was revealed by X-ray crystallography, confirming our initial in silico binding model. Furthermore, the high resolution of the complex structure allowed for the placement of the Gly97-Ser108 flexible loop, thus revealing its role in binding of this class of compounds. The crystal structure of the complex protein G24 and inhibitor 18 provides valuable information for further optimization of this novel class of DNA gyrase B inhibitors.

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Recent Developments of DNA Poisons - Human DNA Topoisomerase IIα Inhibitors - as Anticancer Agents

Pogorelčnik

Perdih²,

Šolmajer

2013

CPD

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DNA topoisomerases are an important family of enzymes that catalyze the induction of topological changes in the DNA molecule. Their ability to modulate the topology of the DNA makes DNA topoisomerases a key player in several vital cell processes such as replication, transcription, chromosome separation and segregation. Consequently, they already represent an important collection of macromolecular targets for some of the established anticancer drugs on the market as well as serve as templates in the development of novel anticancer drugs especially supported by recent structural advances in the field. The aim of this review is to provide an overview of the recent developments in the field of DNA poisons - a major class of human topoisomerase IIα inhibitors - of which several are already in clinical use. Due to frequently experienced occurrence of serious side effects of these molecules during therapy, especially cardiotoxicity issues, further drug design efforts were initiated already yielding novel promising compounds that have overcome this issue and already entered into clinical studies. Some of the presented and discussed chemical classes include intercalators, non-intercalators and redox-dependent poisons of human topoisomerase IIα. In particular, this review focuses on the currently available structure-based standpoint of molecular design and on the medicinal chemist's perspective of this field of anticancer drug design.

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The CWB2 Cell Wall-Anchoring Module Is Revealed by the Crystal Structures of the Clostridium difficile Cell Wall Proteins Cwp8 and Cwp6

et al. 2017

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Bacterial cell wall proteins play crucial roles in cell survival, growth, and environmental interactions. In Gram-positive bacteria, cell wall proteins include several types that are non-covalently attached via cell wall binding domains. Of the two conserved surface-layer (S-layer)-anchoring modules composed of three tandem SLH or CWB2 domains, the latter have so far eluded structural insight. The crystal structures of Cwp8 and Cwp6 reveal multi-domain proteins, each containing an embedded CWB2 module. It consists of a triangular trimer of Rossmann-fold CWB2 domains, a feature common to 29 cell wall proteins in Clostridium difficile 630. The structural basis of the intact module fold necessary for its binding to the cell wall is revealed. A comparison with previously reported atomic force microscopy data of S-layers suggests that C. difficile S-layers are complex oligomeric structures, likely composed of several different proteins.

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Targeted molecular dynamics simulation studies of binding and conformational changes in E. coli MurD

Perdih

Kotnik²,

Hodošček

et al. 2007

Proteins

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Enzymes involved in the biosynthesis of bacterial peptidoglycan, an essential cell wall polymer unique to prokaryotic cells, represent a highly interesting target for antibacterial drug design. Structural studies of E. coli MurD, a three-domain ATP hydrolysis driven muramyl ligase revealed two inactive open conformations of the enzyme with a distinct C-terminal domain position. It was hypothesized that the rigid body rotation of this domain brings the enzyme to its closed active conformation, a structure, which was also determined experimentally. Targeted molecular dynamics 1 ns-length simulations were performed in order to examine the substrate binding process and gain insight into structural changes in the enzyme that occur during the conformational transitions into the active conformation. The key interactions essential for the conformational transitions and substrate binding were identified. The results of such studies provide an important step toward more powerful exploitation of experimental protein structures in structure-based inhibitor design.

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Binding free energy calculations of N-sulphonyl-glutamic acid inhibitors of MurD ligase

2009

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The increasing incidence of bacterial resistance to most available antibiotics has underlined the urgent need for the discovery of novel efficacious antibacterial agents. The biosynthesis of bacterial peptidoglycan, where the MurD enzyme is involved in the intracellular phase of UDP-MurNAc-pentapeptide formation, represents a collection of highly selective targets for novel antibacterial drug design. Structural studies of N-sulfonyl-glutamic acid inhibitors of MurD have made possible the examination of binding modes of this class of compounds, providing valuable information for the lead optimization phase of the drug discovery cycle. Binding free energies were calculated for a series of MurD N-sulphonyl-Glu inhibitors using the linear interaction energy (LIE) method. Analysis of interaction energy during the 20-ns MD trajectories revealed non-polar van der Waals interactions as the main driving force for the binding of these inhibitors, and excellent agreement with the experimental free energies was obtained. Calculations of binding free energies for selected moieties of compounds in this structural class substantiated even deeper insight into the source of inhibitory activity. These results constitute new valuable information to further assist the lead optimization process.

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Andrej Perdih

Structure-Based Discovery of Substituted 4,5′-Bithiazoles as Novel DNA Gyrase Inhibitors

Recent Developments of DNA Poisons - Human DNA Topoisomerase IIα Inhibitors - as Anticancer Agents

The CWB2 Cell Wall-Anchoring Module Is Revealed by the Crystal Structures of the Clostridium difficile Cell Wall Proteins Cwp8 and Cwp6

Targeted molecular dynamics simulation studies of binding and conformational changes in E. coli MurD

Binding free energy calculations of N-sulphonyl-glutamic acid inhibitors of MurD ligase

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Andrej Perdih

Structure-Based Discovery of Substituted 4,5′-Bithiazoles as Novel DNA Gyrase Inhibitors

Recent Developments of DNA Poisons - Human DNA Topoisomerase II&alpha; Inhibitors - as Anticancer Agents

The CWB2 Cell Wall-Anchoring Module Is Revealed by the Crystal Structures of the Clostridium difficile Cell Wall Proteins Cwp8 and Cwp6

Targeted molecular dynamics simulation studies of binding and conformational changes in E. coli MurD

Binding free energy calculations of N-sulphonyl-glutamic acid inhibitors of MurD ligase

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Resources

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Recent Developments of DNA Poisons - Human DNA Topoisomerase IIα Inhibitors - as Anticancer Agents