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2. The adaptability of the ion binding site by the Ag(I)/Cu(I) periplasmic chaperone SilF

Author

Ryan M. Lithgo, Marko Hanževački, Gemma Harris, Jos J. A. G. Kamps, Ellie Holden, Justin LP Benesch, Christof M. Jäger, Anna K. Croft, Jon L. Hobman, Allen M. Orville, Andrew Quigley, Stephen B. Carr, and David J. Scott

Abstract

The periplasmic chaperone SilF has been identified as part of an Ag(I) detoxification system in Gram negative bacteria. Sil proteins also bind Cu(I), but with reported weaker affinity, therefore leading to the designation of a specific detoxification system for Ag(I). Using isothermal titration calorimetry we show that binding of both ions is not only tighter than previously thought, but of very similar affinities. We investigated the structural origins of ion binding using molecular dynamics and QM/MM simulations underpinned by structural and biophysical experiments. The results of this analysis showed that the binding site adapts to accommodate either ion, with key interactions with the solvent in the case of Cu(I). The implications of this are that Gram negative bacteria do not appear to have evolved a specific Ag(I) efflux system but take advantage of the existing Cu(I) detoxification system. Therefore, there are consequences for how we define a particular metal resistance mechanism and understand its evolution in the environment.

Published
2023
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6. Dynamic Covalent Self-Assembly of Chloride- and Ion-Pair-Templated Cryptates

Author

Selina Hollstein, Oleksandr Shyshov, Marko Hanževački, Jie Zhao, Tamara Rudolf, Christof M. Jäger, and Max von Delius

Subjects
General Chemistry, Catalysis
Abstract

While supramolecular hosts capable of binding and transporting anions and ion pairs are now widely available, self-assembled architectures are still rare, even though they offer an inherent mechanism for the release of the guest ion(s). In this work, we report the dynamic covalent self-assembly of tripodal, urea-based anion cryptates that are held together by two orthoester bridgeheads. These hosts exhibit affinity for anions such as Cl

Published
2022

7. Engineering improved ethylene production: Leveraging systems Biology and adaptive laboratory evolution

Author

Salah Abdelrazig, Samantha J. Bryan, Pin-Ching Maness, Alexander M.W. Van Hagen, Paul A. Dalby, Dong-Hyun Kim, Nicole Pearcy, Marko Hanževački, Sophie Vaud, Jianping Yu, Carrie Eckert, Muhammad Ehsaan, Laudina Safo, Pierre-Yves Colin, Jamie Twycross, Nigel P. Minton, Edward Spence, Rajesh Reddy Bommareddy, Sean Craig, Alex Conradie, James Fothergill, Thomas Millat, Magdalene Jonczyk, Christof M. Jäger, and Sean A. Lynch

Subjects
Ethylene, Chemistry, Systems Biology, Systems biology, Mutant, C100, Pseudomonas syringae, Substrate (chemistry), Bioengineering, C500, Ethylenes, Directed evolution, Applied Microbiology and Biotechnology, Metabolic engineering, chemistry.chemical_compound, Metabolic Engineering, Biochemistry, Escherichia coli, Fermentation, Heterologous expression, Laboratories, Biotechnology
Abstract

Ethylene is a small hydrocarbon gas widely used in the chemical industry. Annual worldwide production currently exceeds 150 million tons, producing considerable amounts of CO2 contributing to climate change. The need for a sustainable alternative is therefore imperative. Ethylene is natively produced by several different microorganisms, including Pseudomonas syringae pv. phaseolicola via a process catalyzed by the ethylene forming enzyme (EFE), subsequent heterologous expression of EFE has led to ethylene production in non-native bacterial hosts including E. coli and cyanobacteria. However, solubility of EFE and substrate availability remain rate limiting steps in biological ethylene production. We employed a combination of genome scale metabolic modelling, continuous fermentation, and protein evolution to enable the accelerated development of a high efficiency ethylene producing E. coli strain, yielding a 49-fold increase in production, the most significant improvement reported to date. Furthermore, we have clearly demonstrated that this increased yield resulted from metabolic adaptations that were uniquely linked to the EFE enzyme (WT vs mutant). Our findings provide a novel solution to deregulate metabolic bottlenecks in key pathways, which can be readily applied to address other engineering challenges.

Published
2021

8. Photodegradation, toxicity and density functional theory study of pharmaceutical metoclopramide and its photoproducts

Author

Marko Hanževački, Klaudija Ivanković, Kristina Tolić, Dario Dabić, Sandra Babić, Irena Škorić, Martina Biošić, and Bojana Žegura

Subjects
Pollutant, Environmental Engineering, Photolysis, Chemistry, Metoclopramide, Kinetics, Photodissociation, Quantum yield, Alkylation, Photochemistry, Pollution, Ferric Compounds, Hydroxylation, chemistry.chemical_compound, Pharmaceutical Preparations, photolysis, quantum yield, degradation products, density functional theory, toxicity, Sunlight, Environmental Chemistry, Degradation (geology), Photodegradation, Waste Management and Disposal, Density Functional Theory, Water Pollutants, Chemical
Abstract

Pharmaceuticals as ubiquitous organic pollutants in the aquatic environment represent substances whose knowledge of environmental fate is still limited. One such compound is metoclopramide, whose direct and indirect photolysis and toxicological assessment have been studied for the first time in this study. Experiments were performed under solar radiation, showing metoclopramide as a compound that can easily degrade in different water matrices. The effect of pH-values showed the faster degradation at pH = 7, while the highly alkaline conditions at pH = 11 slowed photolysis. The highest value of quantum yield of metoclopramide photodegradation (ϕ = 43.55·10−4) was obtained at pH = 7. Various organic and inorganic substances (NO3−, Fe(III), HA, Cl−, Br−, HCO3−, SO42−), commonly present in natural water, inhibited the degradation by absorbing light. In all experiments, kinetics followed pseudo-first-order reaction with r2 greater than 0.98. The structures of the photolytic degradation products were tentatively identified, and degradation photoproducts were proposed. The hydroxylation of the aromatic ring and the amino group's dealkylation were two major photoproduct formation mechanisms. Calculated thermochemical quantities are in agreement with the experimentally observed stability of different photoproducts. Reactive sites in metoclopramide were studied with conceptual density functional theory and regions most susceptible to •OH attack were characterized. Metoclopramide and its degradation products were neither genotoxic for bacteria Salmonella typhimurium in the SOS/umuC assay nor acutely toxic for bacteria Vibrio fischeri.

Published
2021

9. Functional self-assembled nanovesicles based on β-cyclodextrin, liposomes and adamantyl guanidines as potential nonviral gene delivery vectors

Author

Josip Požar, Marko Hanževački, Tomislav Vuletić, Adela Štimac, Ruža Frkanec, Marina Šekutor, Katarina Leko, Ajasja Ljubetič, Matea Tokić, and Leo Frkanec

Subjects
Supramolecular chemistry, Adamantane, Fluorescence correlation spectroscopy, 02 engineering and technology, Molecular Dynamics Simulation, Gene delivery, 010402 general chemistry, Guanidines, 01 natural sciences, Biochemistry, Diffusion, chemistry.chemical_compound, Cell Line, Tumor, Phosphatidylcholine, Amphiphile, Humans, Physical and Theoretical Chemistry, chemistry.chemical_classification, Drug Carriers, Liposome, Cyclodextrin, beta-Cyclodextrins, Organic Chemistry, adamantyl guanidine, amphiphilic ß-cyclodextrin vesicles, host-guest complexes, liposomes, nonviral gene delivery vectors, supramolecular systems, Gene Transfer Techniques, DNA, 021001 nanoscience & nanotechnology, Combinatorial chemistry, 0104 chemical sciences, Electrophoresis, HEK293 Cells, chemistry, Liposomes, Phosphatidylcholines, 0210 nano-technology, Plasmids
Abstract

Multicomponent self-assembled supramolecular nanovesicles based on an amphiphilic derivative of β-cyclodextrin and phosphatidylcholine liposomes (PC-liposomes) functionalized with four structurally different adamantyl guanidines were prepared and characterized. Incorporation efficiency of the examined adamantyl guanidines as well as size and surface charge of the prepared supramolecular nanovesicles was determined. Changes in the surface charge of the prepared nanovesicles confirmed that guanidinium groups were exposed on the surface. ITC and 1H NMR spectroscopy complemented by molecular dynamics (MD) simulations were used to elucidate the structural data and stability of the inclusion complexes of β-cyclodextrin and adamantyl guanidines (AG1–5). The results are consistent and point to a significant contribution of the guanylhydrazone residue to the complexation process for AG1 and AG2 with β-cyclodextrin. In order to evaluate the potential of the self- assembled supramolecular nanomaterial as a nonviral gene delivery vector, fluorescence correlation spectroscopy was used. It showed that the prepared nanovesicles functionalized with adamantyl guanidines AG1–4 effectively recognize and bind the fluorescently labelled DNA. Furthermore, gel electrophoretic assay confirmed the formation of nanoplexes of functionalized nanovesicles and plasmid DNA. These findings together suggest that the designed supramolecular nanovesicles could be successfully applied as nonviral gene delivery vectors.

Published
2019
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10. Computational Tale of Two Enzymes: Glycerol Dehydration With or Without B12

Author

Marko Hanževački, Gregory M. Sandala, Leo Radom, Borislav Kovačević, Danijela Barić, David M. Smith, Darko Babić, and Luka Bilić

Subjects
chemistry.chemical_classification, 010405 organic chemistry, Chemistry, Stereochemistry, Substrate (chemistry), Selective catalytic reduction, General Chemistry, Hydrogen atom, 010402 general chemistry, medicine.disease, 01 natural sciences, Biochemistry, Catalysis, 0104 chemical sciences, chemistry.chemical_compound, Colloid and Surface Chemistry, Enzyme, Biocatalysis, medicine, Glycerol, Dehydration, Theoretical Chemistry, B12-dependent GDH, B12-indipendent B12, QM/MM, mechanism of catalysis
Abstract

We present a series of QM/MM calculations aimed at understanding the mechanism of the biological dehydration of glycerol. Strikingly and unusually, this process is catalyzed by two different radical enzymes, one of which is a coenzyme-B12-dependent enzyme and the other which is a coenzyme-B12-independent enzyme. We show that glycerol dehydration in the presence of the coenzyme-B12-dependent enzyme proceeds via a 1, 2-OH shift, which benefits from a significant catalytic reduction in the barrier. In contrast, the same reaction in the presence of the coenzyme-B12-independent enzyme is unlikely to involve the 1, 2-OH shift ; instead, a strong preference for direct loss of water from a radical intermediate is indicated. We show that this preference, and ultimately the evolution of such enzymes, is strongly linked with the reactivities of the species responsible for abstracting a hydrogen atom from the substrate. It appears that the hydrogen-reabstraction step involving the product-related radical is fundamental to the mechanistic preference. The unconventional 1, 2-OH shift seems to be required to generate a product-related radical of sufficient reactivity to cleave the relatively inactive C–H bond arising from the B12 cofactor. In the absence of B12, it is the relatively weak S–H bond of a cysteine residue that must be homolyzed. Such a transformation is much less demanding, and its inclusion apparently enables a simpler overall dehydration mechanism.

Published
2018
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11. The Influence of Chemical Change on Protein Dynamics: A Case Study with Pyruvate Formate‐Lyase

Author

Marko Hanževački, Ana-Sunčana Smith, David M. Smith, Radha D. Banhatti, and Karmen Condic-Jurkic

Subjects
Stereochemistry, Coenzyme A, Molecular Dynamics Simulation, Crystallography, X-Ray, 010402 general chemistry, 01 natural sciences, Catalysis, chemistry.chemical_compound, Molecular dynamics, Pyruvate formate lyase, Acetyltransferases, Catalytic Domain, 0103 physical sciences, Pyruvic Acid, Escherichia coli, Formate, Chemical change, chemistry.chemical_classification, Binding Sites, biology, 010304 chemical physics, 010405 organic chemistry, Protein dynamics, Organic Chemistry, Active site, Substrate (chemistry), Acetylation, General Chemistry, Pyruvate formate-lyase (PFL), molecular dynamics, 0104 chemical sciences, Enzyme, Front cover, chemistry, biology.protein, Biocatalysis
Abstract

Pyruvate formate-lyase (PFL) catalyzes the reversible conversion of pyruvate and coenzyme A (CoA) into formate and acetyl-CoA in two half-reactions. For the second half-reaction to take place, the S@H group of CoA must enter the active site of the enzyme to retrieve a proteinbound acetyl group. However, CoA is bound at the protein surface, whereas the active site is buried in the protein interior, some 20–30 a away. The PFL system was therefore subjected to a series of extensive molecular dynamics simulations (in the ms range) and a host of advanced analysis procedures. Models representing PFL before and after the first half-reaction were used to examine the possible effect of enzyme acetylation. All simulated structures were found to be relatively stable compared to the initial crystal structure. Although the adenine portion of CoA remained predominantly bound at the protein surface, the binding of the S@H group was significantly more labile. A potential entry channel for CoA, which would allow the S@H group to reach the active site, was identified and characterized. The channel was found to be associated with accentuated fluctuations and a higher probability of being in an open state in acetylated systems. This result suggests that the acetylation of the enzyme assumes a prominent functional role, whereby the formation of the acyl intermediate serves to initiate a subtle signaling cascade that influences the protein dynamics and facilitates the entry of the second substrate.

Published
2019
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12. Exploring Reactive Conformations of Coenzyme A during Binding and Unbinding to Pyruvate Formate–Lyase

Author

Marko Hanževački, Karmen Condic-Jurkic, Ana-Sunčana Smith, Radha D. Banhatti, and David M. Smith

Subjects
Models, Molecular, Protein Conformation, Stereochemistry, Coenzyme A, Molecular Dynamics Simulation, 010402 general chemistry, 01 natural sciences, chemical structure, peptides and proteins, mathematical methods, computational chemistry, computer simulations, 03 medical and health sciences, chemistry.chemical_compound, Molecular dynamics, Protein structure, Acetyltransferases, Formate, Physical and Theoretical Chemistry, Binding site, Theoretical Chemistry, 030304 developmental biology, 0303 health sciences, Binding Sites, biology, Active site, 0104 chemical sciences, chemistry, Catalytic cycle, biology.protein, Umbrella sampling
Abstract

Pyruvate formate–lyase (PFL) is a glycyl radical enzyme that converts pyruvate and coenzyme A (CoA) into formate and acetyl-CoA in two half-reactions. Recently, we showed that the acetylation of the PFL active site in the first half-reaction induces subtle conformational changes, leading to the opening of a potential channel for CoA entry. Entry of CoA into the active site is crucial for the second half-reaction, involving the acetyl transfer to CoA, and the completion of the catalytic cycle. Using steered molecular dynamics (SMD) simulations, performed on acetylated and nonacetylated monomeric PFL model systems, we first of all investigate the possible entry/exit pathways of CoA with respect to the active site through the previously identified channel. We then perform umbrella sampling simulations on multiple snapshots from SMD trajectories as well as unrestrained molecular dynamics simulations starting from the final structures obtained from entry SMD, with a view to identifying possible bound states of CoA in the near vicinity of the active site. Detailed study of the unrestrained dissociation processes reveals the presence of stable and reactive bound states of CoA close to the active site, one of which is in an ideal position for triggering the second half-reaction. Examination of the spatial distributions associated with the reactive bound states allows us to discuss the free energy barriers. Umbrella sampling, performed on snapshots from unrestrained dynamics confirms the above findings. The significance of the results for the catalysis are discussed for both acetylated and nonacetylated systems.

Published
2019

13. Front Cover: Solvophobically Driven Complexation of Adamantyl Mannoside with β‐Cyclodextrin in Water and Structured Organic Solvents (Chem. Eur. J. 23/2020)

Author

Marko Hanževački, Katarina Pičuljan, Rosana Ribić, Zlatko Brkljača, Josip Požar, and Katarina Leko

Subjects
chemistry.chemical_classification, Hydrophobic effect, Front cover, Cyclodextrin, chemistry, Organic Chemistry, Polymer chemistry, General Chemistry, Solvent effects, Catalysis
Published
2020
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14. Computational Tale of Two Enzymes: Glycerol Dehydration With or Without B

Author

Borislav, Kovačević, Danijela, Barić, Darko, Babić, Luka, Bilić, Marko, Hanževački, Gregory M, Sandala, Leo, Radom, and David M, Smith

Subjects
Glycerol, Models, Molecular, Klebsiella pneumoniae, Propane, Vitamin B 12, Biocatalysis, Clostridium butyricum, Glyceraldehyde, Hydro-Lyases
Abstract

We present a series of QM/MM calculations aimed at understanding the mechanism of the biological dehydration of glycerol. Strikingly and unusually, this process is catalyzed by two different radical enzymes, one of which is a coenzyme-B

Published
2018

15. A computational study of the chlorination and hydroxylation of amines by hypochlorous acid

Author

Valerije Vrček, Marko Hanževački, Davor Šakić, and David M. Smith

Subjects
Reaction mechanism, Aqueous solution, Molecular Structure, Hypochlorous acid, MD simulation, DFT, reaction mechanism, HOCl, amines, Methylamine, Morpholines, Organic Chemistry, Inorganic chemistry, Solvation, Hydroxylation, Biochemistry, Transition state, Hypochlorous Acid, Molecular Docking Simulation, chemistry.chemical_compound, Molecular dynamics, Piperidines, chemistry, Computational chemistry, Amines, Chlorine, Physical and Theoretical Chemistry, Solvent effects
Abstract

The reactions of hypochlorous acid (HOCl) with ammonia, (di)methylamine, and heterocyclic amines have been studied computationally using double-hybrid DFT methods (B2PLYP-D and BK-PLYP) and a G3B3 composite scheme. In the gas phase the calculated energy barriers for N- and/or C-hydroxylation are ca. 100 kJ mol(-1) lower than the barrier for N-chlorination of amines. In the model solvent, however, the latter process becomes kinetically more favored. The explicit solvent effects are crucial for determination of the reaction mechanism. The N-chlorination is extremely susceptible to the presence of explicit water molecules, while no beneficial solvation effect has been found for the N- or C-hydroxylation of amines. The origin of the observed solvent effects arises from differential solvation of the respective transition states for chlorine- and oxygen-transfers, respectively. The nature of solvation of the transition state structures has been explored in more detail by classical molecular dynamics (MD) simulation. In agreement with the quantum mechanical approach, the most stable structural motif, which includes the amine, HOCl, and two reactive waters, has been identified during the MD simulation. The inclusion of 5 or 6 explicit water molecules is required to reproduce the experimental barriers for HOCl-induced formation of N-chloramines in an aqueous environment.

Published
2015
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16. Application of machine learning for herbicide characterization

Author

Pehar, Vesna, Oršolić, Davor, Stepanić, Višnja, Darko, Babić, Danijela, Barić, Marko, Cvitaš, Ines, Despotović, Nađa, Došlić, Marko, Hanževački, Tomica, Hrenar, Borislav, Kovačević, Ivan, Ljubić, Zlatko, Mihalić, Davor, Šakić, Tana, Tandarić, Mario, Vazdar, Robert, Vianello, Valerije, Vrček, and Tin, Weitner

Subjects
herbicides, machine learning, ADME, toxicity
Abstract

Herbicides are chemical molecules used for destruction of weeds. Massive usage of herbicides has resulted in two global problems: increase in weed resistance and harmful impact of human health [1, 2]. In order to facilitate development of novel, more specific herbicides and of strategies for impeding the weed resistance, we have carried out extensive in silico analysis of the set of herbicides. Herein, we present results revealing links between structural, physicochemical, ADME (Absorption, Distribution, Metabolism, Excretion) and toxic features for herbicides (Figure 1). The analysis has been done by using proper machine learning approaches. References: [1] A. Forouzesh, E. Zand, S. Soufizadeh, S. S. Foroushani, Weed Res. 55 (2015) 334-358. [2] V. I. Lushchak, T. M. Matviishyn, V. V. Husak, J. M. Storey, K. B. Storey, EXCLI J. 17 (2018) 1101-1136.

Published
2019

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