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International Microbiology : the... Dec 2019Azurin, a bacteriocin produced by a human gut bacterium Pseudomonas aeruginosa, can reveal selectively cytotoxic and induce apoptosis in cancer cells. After overcoming...
Molecular screening and genetic diversity analysis of anticancer Azurin-encoding and Azurin-like genes in human gut microbiome deduced through cultivation-dependent and cultivation-independent studies.
Azurin, a bacteriocin produced by a human gut bacterium Pseudomonas aeruginosa, can reveal selectively cytotoxic and induce apoptosis in cancer cells. After overcoming two phase I trials, a functional region of Azurin called p28 has been approved as a drug for the treatment of brain tumor glioma by FDA. The present study aims to improve a screening procedure and assess genetic diversity of Azurin genes in P. aeruginosa and Azurin-like genes in the gut microbiome of a specific population in Vietnam and global populations. Firstly, both cultivation-dependent and cultivation-independent techniques based on genomic and metagenomic DNAs extracted from fecal samples of the healthy specific population were performed and optimized to detect Azurin genes. Secondly, the Azurin gene sequences were analyzed and compared with global populations by using bioinformatics tools. Finally, the screening procedure improved from the first step was applied for screening Azurin-like genes, followed by the protein synthesis and NCI in vitro screening for anticancer activity. As a result, this study has successfully optimized the annealing temperatures to amplify DNAs for screening Azurin genes and applying to Azurin-like genes from human gut microbiota. The novelty of this study is the first of its kind to classify Azurin genes into five different genotypes at a global scale and confirm the potential anticancer activity of three Azurin-like synthetic proteins (Cnazu1, Dlazu11, and Ruazu12). The results contribute to the procedure development applied for screening anticancer proteins from human microbiome and a comprehensive understanding of their therapeutic response at a genetic level.
Topics: Adolescent; Adult; Azurin; Child; Culture Media; Feces; Female; Gastrointestinal Microbiome; Genetic Variation; Humans; Male; Phylogeny; Pseudomonas aeruginosa; Young Adult
PubMed: 30895406
DOI: 10.1007/s10123-019-00070-8 -
Journal of Chemical Theory and... Jun 2021Biomolecules with metal ion(s) (e.g., metalloproteins) play many important biological roles. However, accurate structural determination of metalloproteins, particularly...
Biomolecules with metal ion(s) (e.g., metalloproteins) play many important biological roles. However, accurate structural determination of metalloproteins, particularly those containing transition metal ion(s), is challenging due to their complicated electronic structure, complex bonding of metal ions, and high number of conformations in biomolecules. Quantum refinement, which was proposed to combine crystallographic data with computational chemistry methods by several groups, can improve the local structures of some proteins. In this study, a quantum refinement method combining several multiscale computational schemes with experimental (X-ray diffraction) information was developed for metalloproteins. Various quantum refinement approaches using different ONIOM (our own -layered integrated molecular orbital and molecular mechanics) combinations of quantum mechanics (QM), semiempirical (SE), and molecular mechanics (MM) methods were conducted to assess the performance and reliability on the refined local structure in two metalloproteins. The structures for two (Cu- or Zn-containing) metalloproteins were refined by combining two-layer ONIOM2(QM1/QM2) and ONIOM2(QM/MM) and three-layer ONIOM3(QM1/QM2/MM) schemes with experimental data. The accuracy of the quantum-refined metal binding sites was also examined and compared in these multiscale quantum refinement calculations. ONIOM3(QM/SE/MM) schemes were found to give good results with lower computational costs and were proposed to be a good choice for the multiscale computational scheme for quantum refinement calculations of metal binding site(s) in metalloproteins with high efficiency. Additionally, a two-center ONIOM approach was employed to speed up the quantum refinement calculations for the Zn metalloprotein with two remote active sites/ligands. Moreover, a recent quantum-embedding wavefunction-in-density functional theory (WF-in-DFT) method was also adopted as the high-level method in unprecedented ONIOM2(CCSD-in-B3LYP/MM) and ONIOM3(CCSD-in-B3LYP/SE/MM) calculations, which can be regarded as novel pseudo-three- and pseudo-four-layer ONIOM methods, respectively, to refine the key Zn binding site at the coupled-cluster singles and doubles (CCSD) level. These refined results indicate that multiscale quantum refinement schemes can be used to improve the structural accuracy obtained for local metal binding site(s) in metalloproteins with high efficiency.
Topics: Azurin; Binding Sites; Catalytic Domain; Crystallography, X-Ray; Histone Acetyltransferases; Ligands; Metalloproteins; Metals; Molecular Dynamics Simulation; Quantum Theory
PubMed: 34032440
DOI: 10.1021/acs.jctc.1c00148 -
3 Biotech Jul 2019In the present study, the simultaneous application of gene of and - antigen on the induction of immune responses against breast cancer tumors was investigated in...
In the present study, the simultaneous application of gene of and - antigen on the induction of immune responses against breast cancer tumors was investigated in BALB/c mice. The pBudCE4.1-azurin-MAM-A recombinant vector was generated and prepared at a large scale. This recombinant vector alone or combined with chitosan nanoparticles was infused into the hip muscle of animals. Animals were divided into the "prevention" and "therapy" categories. The animals of prevention category were first, immunized by a recombinant vector and then exposed to chemical cancer inducers; while the animals in the therapy category were first treated with chemical compounds and then infused by a recombinant plasmid. The tumor tissues, infusion sites, and blood specimens were collected and examined by serological, molecular, and histological tests. The breast tumor incidence in the infused animals by recombinant plasmid alone or combined with nanoparticles (in both prevention and therapy categories) compared with infused mice by empty pBudCE4.1 vector was significantly decreased (< 0.05). These results were supported by histological studies using H&E staining. The ELISA and q-real-time PCR techniques showed the range of IFN-γ, IL-12, IL-4, and IL-17A cytokines in the infused mice by recombinant vector alone or combined with nanoparticles compared to the healthy mice and infused animals by intact pBudCE4.1 were significantly increased (< 0.05). Accordingly, the expression of the tumor markers , , and were significantly decreased in treated mice either by the sole recombinant vector or combined with nanoparticles (< 0.05). These findings indicated that pBudCE4.1-azurin-MAM-A recombinant vector plays an essential role against the formation and expansion of breast tumors in the animal model. In addition, this recombinant vector is safe and has the proper ability to stimulate the immune system. In addition, the chitosan nanoparticle represents a promising adjuvant for DNA vaccine delivery, which improves the immune system stimulation and boosts the vaccine performance.
PubMed: 31245235
DOI: 10.1007/s13205-019-1804-7 -
The Journal of Physical Chemistry. B Apr 2022We investigate the events characterizing the steps of the unfolding pathway of blue copper metalloprotein azurin using replica exchange molecular dynamics (REMD). Our...
We investigate the events characterizing the steps of the unfolding pathway of blue copper metalloprotein azurin using replica exchange molecular dynamics (REMD). Our studies show that the unfolding of azurin begins with the melting of α-helix and β-sheets II and V. This is followed by the melting of other β-sheets and the exposure of hydrophobic protein core to the solvent, resulting in disruptions of its tertiary structure. Free energy surfaces constructed at different temperatures portray different basins that signify the stability of different melted structures in the unfolding process. The contact maps at different temperatures reveal that the strong hydrophobic interaction within the core of the protein is the vital force that renders high stability to this protein. Analysis of the individual β-sheets by looking into their amino acid sequence shows that β-sheets with charged side chains on the surface melt fast compared to others. The β-barrel of azurin is able to dynamically rearrange, and it helps the protein to preserve its hydrophobic core, holding back the native topology from melting fast. B-factor analysis shows that residues of β-sheets III, IV, and VII deviate less from their initial structure at the transition temperature.
Topics: Azurin; Copper; Hydrophobic and Hydrophilic Interactions; Metalloproteins; Molecular Dynamics Simulation; Protein Folding
PubMed: 35324174
DOI: 10.1021/acs.jpcb.2c00622 -
The Journal of Physical Chemistry... Dec 2023We conducted a theoretical study of electron transport through junctions of the blue-copper azurin from . We found that single-site hopping can lead to either higher or...
We conducted a theoretical study of electron transport through junctions of the blue-copper azurin from . We found that single-site hopping can lead to either higher or lower current values compared to fully coherent transport. This depends on the structural details of the junctions as well as the alignment of the protein orbitals. Moreover, we show how the asymmetry of the curves can be affected by the position of the tip in the junction and that, under specific conditions, such a hopping mechanism is consistent with a fairly low temperature dependence of the current. Finally, we show that increasing the number of hopping sites leads to higher hopping currents. Our findings, from fully quantum calculations, provide deep insight to help guide the interpretation of experimental curves on highly complex systems.
PubMed: 38059566
DOI: 10.1021/acs.jpclett.3c02702 -
Biomolecules Apr 2023Due to the similarity in the basic coordination behavior of their mono-charged cations, silver biochemistry is known to be linked to that of copper in biological...
Due to the similarity in the basic coordination behavior of their mono-charged cations, silver biochemistry is known to be linked to that of copper in biological systems. Still, Cu/ is an essential micronutrient in many organisms, while no known biological process requires silver. In human cells, copper regulation and trafficking is strictly controlled by complex systems including many cytosolic copper chaperones, whereas some bacteria exploit the so-called "blue copper" proteins. Therefore, evaluating the controlling factors of the competition between these two metal cations is of enormous interest. By employing the tools of computational chemistry, we aim to delineate the extent to which Ag might be able to compete with the endogenous copper in its Type I (T1Cu) proteins, and where and if, alternatively, it is handled uniquely. The effect of the surrounding media (dielectric constant) and the type, number, and composition of amino acid residues are taken into account when modelling the reactions in the present study. The obtained results clearly indicate the susceptibility of the T1Cu proteins to a silver attack due to the favorable composition and geometry of the metal-binding centers, along with the similarity between the Ag/Cu-containing structures. Furthermore, by exploring intriguing questions of both metals' coordination chemistry, an important background for understanding the metabolism and biotransformation of silver in organisms is provided.
Topics: Humans; Copper; Silver
PubMed: 37189429
DOI: 10.3390/biom13040681 -
Accounts of Chemical Research May 2023"What I cannot create, I do not understand"─Richard Feynman. This sentiment motivates the entire field of artificial metalloenzymes. Naturally occurring enzymes...
"What I cannot create, I do not understand"─Richard Feynman. This sentiment motivates the entire field of artificial metalloenzymes. Naturally occurring enzymes catalyze reactions with efficiencies, rates, and selectivity that generally cannot be achieved in synthetic systems. Many of these processes represent vital building blocks for a sustainable society, including CO conversion, nitrogen fixation, water oxidation, and liquid fuel synthesis. Our inability as chemists to fully reproduce the functionality of naturally occurring enzymes implicates yet-unknown contributors to reactivity. To identify these properties, it is necessary to consider all of the components of naturally occurring metalloenzymes, from the active site metal(s) to large-scale dynamics. In this Account, we describe the holistic development of a metalloprotein-based model that functionally reproduces the acetyl coenzyme A synthase (ACS) enzyme.ACS catalyzes the synthesis of a thioester, acetyl coenzyme A, from gaseous carbon monoxide, a methyl group donated by a cobalt corrinoid protein, and coenzyme A. The active site of ACS contains a bimetallic nickel site coupled to a [4Fe-4S] cluster. This reaction mimics Monsanto's acetic acid synthesis and represents an ancient process for incorporating inorganic carbon into cellular biomass through the primordial Wood-Ljungdahl metabolic pathway. From a sustainability standpoint, the reversible conversion of C substrates into an acetyl group and selective downstream transfer to a thiolate nucleophile offer opportunities to expand this reactivity to the anthropogenic synthesis of liquid fuels. However, substantial gaps in our understanding of the ACS catalytic mechanism coupled with the enzyme's oxygen sensitivity and general instability have limited these applications. It is our hope that development of an artificial metalloenzyme that carries out ACS-like reactions will advance our mechanistic understanding and enable synthesis of robust compounds with the capacity for similar reactivity.To construct this model, we first focused on the catalytic proximal nickel (Ni) site, which has a single metal center bound by three bridging cysteine residues in a "Y"-shaped arrangement. With an initial emphasis on reproducing the general structure of a low-coordinate metal binding site, the type I cupredoxin, azurin, was selected as the protein scaffold, and a nickel center was incorporated into the mononuclear site. Using numerous spectroscopic and computational techniques, including electron paramagnetic resonance (EPR) spectroscopy, nickel-substituted azurin was shown to have similar electronic and geometric structures to the Ni center in ACS. A substrate access channel was installed, and both carbon monoxide and a methyl group were shown to bind individually to the reduced Ni center. The elusive EPR-active S = 1/2 Ni-CH species, which has never been detected in native ACS, was observed in the azurin-based model, establishing the capacity of a biological Ni species to support two-electron organometallic reactions. Pulsed EPR studies on the S = 1/2 Ni-CH species in azurin suggested a noncanonical electronic structure with an inverted ligand field, which was proposed to prevent irreversible site degradation. This model azurin protein was ultimately shown to perform carbon-carbon and carbon-sulfur bond formation using sequential, ordered substrate addition for selective, stoichiometric thioester synthesis. X-ray spectroscopic methods were used to provide characterization of the remaining catalytic intermediates, resolving some debate over key mechanistic details.The overall approach and strategies that we employed for the successful construction of a functional protein-based model of ACS are described in this Account. We anticipate that these principles can be adapted across diverse metalloenzyme classes, providing essential mechanistic details and guiding the development of next-generation, functional artificial metalloenzymes.
Topics: Azurin; Acetyl Coenzyme A; Nickel; Carbon Monoxide; Metalloproteins; Electron Spin Resonance Spectroscopy
PubMed: 37042748
DOI: 10.1021/acs.accounts.2c00824 -
Archives of Biochemistry and Biophysics Jul 2020The active sites of metalloproteins may be mimicked by designing peptides that bind to their respective metal ions. Studying the binding of protein ligands to metal ions...
The active sites of metalloproteins may be mimicked by designing peptides that bind to their respective metal ions. Studying the binding of protein ligands to metal ions along with the associated structural changes is important in understanding metal uptake, transport and electron transfer functions of proteins. Copper-binding metalloprotein azurin is a 128-residue electron transfer protein with a redox-active copper cofactor. Here, we report the copper-binding associated spectroscopic and structural properties of peptide loops (11 and 13 residues) from the copper-binding site of azurin. These peptides develop a β-turn upon copper-binding with a 1:1 Cu:peptide stoichiometry as seen in circular dichroism and exhibit electronic transitions centered at 340 nm and 540 nm. Further addition of copper develops a helical feature along with a shift in the absorption maxima to ~360 nm and ~580 nm at 2:1 Cu:peptide stoichiometry, indicating stoichiometric dependence of copper-binding geometry. Mass spectrometry indicates the copper-binding to cysteine, histidine and methionine in the peptide with 1:1 stoichiometry, and interestingly, dimerization through a disulfide linkage at 2:1 stoichiometry, as observed previously for denatured azurin. Fluorescence quenching studies on peptides with tryptophan further confirm the copper-binding induced changes in the two peptides are bi-phasic.
Topics: Azurin; Catalytic Domain; Copper; Fluorescence; Fluorescence Resonance Energy Transfer; Peptide Fragments; Protein Binding; Protein Conformation; Spectrometry, Mass, Electrospray Ionization; Tryptophan
PubMed: 32343975
DOI: 10.1016/j.abb.2020.108388 -
Physical Chemistry Chemical Physics :... Nov 2020Electron Paramagnetic Resonance (EPR) spectroscopy is a powerful method for unraveling structures and dynamics of biomolecules. Out of the EPR tool box, Pulsed...
Electron Paramagnetic Resonance (EPR) spectroscopy is a powerful method for unraveling structures and dynamics of biomolecules. Out of the EPR tool box, Pulsed Electron-Electron Double Resonance spectroscopy (PELDOR or DEER) enables one to resolve such structures by providing distances between spin centers on the nanometer scale. Most commonly, both spin centers are spin labels or one is a spin label and the other is a paramagnetic metal ion, cluster, amino acid or cofactor radical. Often, the translation of the measured distances into structures is complicated by the long and flexible linker connecting the spin center of the spin label with the biomolecule. Nowadays, this challenge is overcome by computational methods but the currently available approaches have a rather large mean error of roughly 2-3 Å. Here, the new GFN-FF general force-field is combined with the fully automated Conformer Rotamer Ensemble Search Tool (CREST) [P. Pracht et al., Phys. Chem. Chem. Phys., 2020, 22, 7169-7192] to generate conformer ensembles of the R1 side chain (methanthiosulfonate spin label (MTSL) covalently bound to a cysteine) in several cysteine mutants of azurin and T4 lysozyme. In order to determine the Cu2+-R1 and R1-R1 distance distributions, GFN-FF based MD simulations were carried out starting from the most probable R1 conformers found by CREST. The deviation between theory and experiment in mean inter-spin distances was 0.98 Å on average for the mutants of azurin (1.84 Å for T4 lysozyme) and the right modality was obtained. The error of the most probable distances for each mode was only 0.76 Å in the case of azurin. This CREST/MD procedure does thus enable precise distance-to-structure translations and provides a means to disentangle label from protein conformers.
Topics: Azurin; Macromolecular Substances; Models, Molecular; Muramidase; Mutation; Nitrogen Oxides; Protein Conformation; Spin Labels
PubMed: 33107523
DOI: 10.1039/d0cp04920d -
Molecular Biotechnology Jun 2024Transfection efficiency of the immortalized human breast epithelial cell line MCF-10A remains an issue that needs to be resolved. In this study, it was aimed to deliver...
Transfection efficiency of the immortalized human breast epithelial cell line MCF-10A remains an issue that needs to be resolved. In this study, it was aimed to deliver a recombinant DNA (pCMV-Azu-GFP) to the MCF-10A cells by the magnetofection method using magnetic nanoparticles (MNPs) and a simple magnet to accelerate the DNA delivery. Surface positively modified silica-coated iron oxide MNPs (MSNP-NH) were produced and characterized via TEM, FTIR, and DLS analyses. The recombinant DNA (rDNA) was obtained by the integration of codon-optimized azurin to produce a fusion protein. Then, rDNA cloned in Escherichia coli cells was validated by sequence analysis. The electrostatically conjugated rDNA on MSNP-NH with an enhancer polyethyleneimine (PEI) was studied by agarose gel electrophoresis and the optimum conditions were determined to apply to the cell. A dose-dependent statistical difference was observed on treated cells based on the MTS test. The expression of the fusion protein after magnetofection was determined using laser scanning confocal microscope imaging and western blot analysis. It was observed that the azurin gene could be transferred to MCF-10A cells by magnetofection. Thus, when the azurin gene is used as a breast cancer treatment agent, it can be expressed in healthy cells without toxic effects.
Topics: Female; Humans; Azurin; Cell Line, Tumor; Codon; DNA, Ribosomal; Escherichia coli; Magnetic Iron Oxide Nanoparticles; Magnetite Nanoparticles; Polyethyleneimine; Recombinant Fusion Proteins; Transfection
PubMed: 37378861
DOI: 10.1007/s12033-023-00798-9