Metal complexes of anhydrotetracycline. 1. A spectrometric study of the Cu(II) and Ni(II) complexes

Influence of Environmental Conditions on the Escape Rates of Biocontained Genetically Engineered Microbes

The development of genetically engineered microbes (GEMs) has resulted in an urgent need to control their persistence in the environment. The use of biocontainment such as kill switches is a critical approach to prevent the unintended proliferation of GEMs; however, the effectiveness of kill switches─reported as escape rates, i.e., the ratio of the number of viable microbes when the kill switch is triggered relative to the number when it is not triggered─is typically assessed under laboratory conditions that do not resemble environmental conditions under which biocontainment must perform. In this study, we discovered that the escape rate of an Escherichia coli GEM biocontained with a CRISPR-based kill switch triggered by anhydrotetracycline (aTc) increased by 3-4 orders of magnitude when deployed in natural surface waters as compared to rich laboratory media. We identified that environmental conditions (e.g., pH, nutrient levels) may contribute to elevated escape rates in multiple ways, including by altering the chemical speciation of the kill switch trigger to reduce its uptake and providing limited nutrients required for the kill switch to function. Our study demonstrated that conditions in the intended environment must be considered in order to design effective GEM biocontainment strategies.

Theoretical and Experimental Studies of the Controlled Release of Tetracycline Incorporated into Bioactive Glasses

Several authors have studied the release profile of drugs incorporated in different devices. However, to the best of our knowledge, although many studies have been done on the release of tetracycline, in these release devices, no study has investigated if the released compound is actually the tetracycline, or, instead, a degraded product. This approach is exploited here. In this work, we analyse the influence of two drying methods on the tetracycline delivery behaviour of synthesised glasses using the sol-gel process. We compare the drying methods results using both theoretical models and practical essays, and analyse the chemical characteristic of the released product in order to verify if it remains tetracycline. Samples were freeze-dried or dried in an oven at 37°C and characterised by several methods such as Fourier transform infrared spectroscopy (FTIR), scanning electron microscopy (SEM), thermogravimetric analysis (TG), differential thermogravimetric analysis (DTG), differential thermal analyses (DTA) and gas adsorption analysis (BET). The released concentration of tetracycline hydrochloride was studied as a function of time, and it was measured by ultraviolet spectrophotometry in the tetracycline wavelength. The drug delivery profiles were reasonably consistent with a diffusion model analysis. In addition, we observed higher release rates for the freeze-dried compared to those dried in an oven at 37°C. This higher release can be attributed to larger pore size for the freeze-dried sample systems with tetracycline, which promoted more water penetration, improving the drug diffusion. The analysis of the solution obtained in the release tests using high-performance liquid chromatography- mass spectrometry (HPLC-MS) confirmed that tetracycline was being released.

Tetracyclines metal complexation: Significance and fate of mutual existence in the environment

Concern over tetracyclines (TCs) complexation with metals in the environment is growing as a new class of emerging contaminants. TCs exist as a different net charged species depending on their dissociation constants, pH and the surrounding environment. One of the key concerns about TCs is its strong tendency to interact with various metal ions and form metal complexes. Moreover, co-existence of TCs and metals in the environment and their interactions has shown increased antibiotic resistance. Despite extensive research on TCs complexation, investigations on their antibiotic efficiency and pharmacological profile in bacteria have been limited. In addition, the current knowledge on TCs metal complexation, their fate and risk assessment in the environment are inadequate to obtain a clear understanding of their consequences on living systems. This indicates that vital and comprehensive studies on TCs-metal complexation, especially towards growing antibiotic resistance trends are required. This review summarizes the role of TCs metal complexation on the development of antibiotic resistance. Furthermore, impact of metal complexation on degradation, toxicity and the fate of TCs in the environment are discussed and future recommendations have been made.

Resonance Rayleigh scattering spectra of tetracycline antibiotic–Cu(II)–titan yellow systems and their applications in analytical chemistry

Tetracycline antibiotics (TCs) such as doxycycline (DOTC), chlortetracycline (CTC), oxytetracycline (OTC), and tetracycline (TC) react with Cu(II) in pH 3.5 BR buffer medium to form 1:1 cationic chelates, which further react with titan yellow to form 2:1 ion association complexes. These result in great enhancement of resonance Rayleigh scattering (RRS) and the appearance of new RRS spectra. The ion association complexes of DOTC, CTC, OTC, and TC have similar spectral characteristics and their maximum RRS wavelengths are all located at 464 nm. The quantitative determination ranges and the detection limits (3sigma) of the four TCs are 0.037-4.8 microg mL(-1) and 11.2 ng mL(-1) for DOTC, 0.041-5.2 microg mL(-1) and 12.4 ng mL(-1) for CTC, 0.050-4.8 microg mL(-1) and 15.1 ng mL(-1) for TC, and 0.088-5.0 microg mL(-1) and 26.3 ng mL(-1) for OTC, respectively. The optimum reaction conditions, the effects of foreign substances, the structure of ternary complexes, and the reaction mechanism are discussed. A sensitive, rapid, and simple RRS method for the determination of DOTC has been developed.

Thermodynamics in [Mn(II)-antibiotics-bacitracin] mixed system: a polarographic approach

Polarographic technique was used to determine the kinetic parameters, thermodynamic parameters and stability constants (log(beta)) of Mn(II) complexes with neomycin, chlortetracycline, oxytetracycline, tetracycline, penicillin V and penicillin G as primary ligands and bacitracin as the secondary ligand, at pH 7.3+/-0.01 and an ionic strength mu=1.0 M (NaClO(4)) at 25 degrees C. The study was also carried out at 35 degrees C to determine the stability constants and thermodynamic parameters viz. enthalpy change (DeltaH), entropy change (DeltaS) and free energy change (DeltaG) of complexes.

A physicochemical study of the tetracycline coordination to oxovanadium(IV)

The interaction of tetracycline and oxovanadium(IV) in aqueous solution was studied by potentiometric and spectrophotometric methods. Oxovanadium(IV) ions form both a positively charged 1:1 and a neutral 2:1 metal-ligand complex with tetracycline. When a 1:1 ligand-to-metal ratio mixture is used at about pH 4.5 the 1:1 species predominates, being replaced at pH 6 by the binuclear complex. The binuclear complex has been isolated and fully characterised. Infrared and EPR studies suggest the existence of two distinct vanadyl binding sites. Our results indicate that the first vanadium coordinates to the BCD-ring system and the second one to the A-ring. Biological implications of the existence of a neutral complex at physiological pH are briefly discussed.

Importance of tautomers in the chemical behavior of tetracyclinesdagger

We advance the concept that tautomerism is crucial for the understanding of the chemical behavior of tetracycline. Indeed, considering four deprotonations, there are 64 different possible tautomers to be considered for tetracycline. Our results indicate that tetracycline is a very adaptive molecule, capable of easily modifying itself through tautomerism in response to various chemical environments. Indeed, its situation in solution can be more accurately pictured as an equilibrium among a diversity of tautomeric species-an equilibrium that can be easily displaced depending on the various possible chemical perturbations, such as varying the pH or the dielectric constant of the solvent. Moreover, we also show that tetracycline could undergo four deprotonations and predict for it a fourth pKa of 13 and refer to our experimental determination of this parameter, which yielded the value of 12. We conclude that tautomerism is essential to the comprehension of the chemical behavior of tetracycline as determined by the semiempirical method AM1 as well as by the self-consistent reaction field method, which estimates the effects of the solvent on the tautomers. All tautomers in their different conformations have been fully optimized for each of the possible degrees of protonation of this molecule. Thus, the relative stabilities of the different tautomeric species have been computed.

A theoretical study of the interaction of anhydrotetracycline with Al(III)

In this article the complexation of anhydrotetracycline (AHTC), the major toxic decomposition product of the antibiotic tetracycline, with Al(III) has been investigated using the AM1 semiempirical and ab initio Hartree-Fock levels of theory. Different modes of complexation have been considered with the structure of tetra- and pentacoordinated complexes being fully optimized. In the gas phase, processes ii and iii, which lead to the complexes with stoichiometry MHL2+, are favored. Structure II ([AlLH2(OH)(H2O)]2+) has the metal coordinated to the O11 and O12 groups and the O3 group protonated and is the global minimum on the potential energy surface for the interaction. In water solution, the Al(III) is predicted to form predominantly a tetracoordinated complex at the Oam and O3 site (V) of the AHTC with the stoichiometry MH2L3+ (process i). The experimental proposal is the complexed form with the metal ion coordinated to the O11-O12 moiety (site II). The intramolecular proton transfer, which leads to the most stable Al(III)-AHTC MHL2+ complex, has not been considered by the experimentalists. The experimental structure was found to be unfavorable in our calculations in both gas phase and water solution. All the semiempirical results are in perfect agreement with the ab initio calculations. So, we suggest that the experimental assignments should be revised, taking into account the results obtained in the present study.

Conformational analysis of the anhydrotetracycline molecule: a toxic decomposition product of tetracycline

Anhydrotetracycline (AHTC) is a toxic decomposition product of the widely used antibiotic tetracycline (TC). The side effects of AHTC have been attributed to the conformational changes in the ring system. In the present study a systematic conformational analysis has been carried out using the semiempirical quantum mechanical AM1 model. The conformational pH dependence has been analyzed through the study of all the ionized species. The results obtained showed two distinct families of conformation, referred to as A and B, with the interconversion process involving a rotation around the C4a-C12a bond. The solvent effect has been considered using the continuum model COSMO. From the population analysis in the gas phase, we conclude that form A should be dominant for the LH3+ and LH2 +/- species and B is the preferred conformer for the L2- ionized form (97.54%). For the LH- derivative, we predict that both conformations should be present in the equilibrium mixture in the gas phase, with the relative concentration found to be 68.47% (A) and 31.53% (B). The inclusion of the solvent does not change the A/B equilibrium for the LH3+ and LH2 +/- species. However, for the LH- form, the equilibrium is shifted to conformer A in water solution. The population analysis in water solution for the L2- suggest the following relative concentrations: A (34.46%) and B (65.54%). The biological activity of the TC parent compound is attributed to the zwitterionic species, which should adopt a twisted conformation. According to the results obtained in the present study, the most abundant form of the LH2 +/- zwitterionic species for the AHTC molecule is the extended one (100% in both the gas phase and water solution). Therefore, from a pharmacodynamic point of view, this conformational difference should be taken into account in order to explain the toxic effects of the anhydrous derivative. Another point related to the structure-activity relationship was analyzed through the investigation of the tautomerization process LH2(0)-->LH2 +/-. The result obtained suggests that the LH2(0) tautomer should be dominant in the gas phase (nonpolar solvent) and adopt a conformation classified as B. In water solution, the tautomer LH2 +/- is present as conformer A (96%). This result is in agreement with the conformation changes involved in the tautomerization process for the OTC active derivative.

Metal complexes of anhydrotetracycline. 2. Absorption and circular dichroism study of Mg(II), Al(III), and Fe(III) complexes. Possible influence of the Mg(II) complex on the toxic side effects of tetracycline

Anhydrotetracycline (AHTC) is the major toxic decomposition product of the antibiotic tetracycline. The complexation of AHTC to Mg(II), Al(III), and Fe(III) was studied in aqueous medium using absorption and circular dichroism measurements. The study of the Mg(II)-AHTC interactions at pH 7 indicated the formation of the MHL and M2L species in which an Mg(II) ion is coordinated to the C11 and C12 oxygens of the BCD ring system. In the M2L species, a second metal ion coordinates to the N4 and O3 positions on ring A, inducing the ligand to adopt the "twisted" conformation. At pH 4, an MHL species is formed with Al(III) by complexation of the metal ion to O11 and O12. At pH 1, Fe(III) forms an MH2L species, probably by coordination of the metal to 012 and 01. The stability constants of all species were calculated. The possible participation of Mg(II) in the mechanism of toxicity of tetracycline is suggested.