Charge-Reversal NaCl/G-Quartets for Aggregation-Induced Mitochondrial MicroRNA Imaging and Ion-Interference Therapy

Mitochondrial therapy is a promising new strategy that offers the potential to achieve precise disease diagnosis or maximum therapeutic response. However, versatile mitochondrial theranostic platforms that integrate biomarker detection and therapy have rarely been exploited. Here, we report a charge-reversal nanomedicine activated by an acidic microenvironment for mitochondrial microRNA (mitomiR) detection and ion-interference therapy. The transporter liposome (DD-DC) was constructed from a pH-responsive polymer and a positively charged phospholipid, encapsulating NaCl nanoparticles with coloading of the aggregation-induced emission (AIE) fluorogens AIEgen-DNA/G-quadruplexes precursor and brequinar (NAB@DD-DC). The negatively charged nanomedicine ensured good blood stability and high tumor accumulation, while the charge-reversal to positive in response to the acidic pH in the tumor microenvironment (TME) and lysosomes enhanced the uptake by tumor cells and lysosome escape, achieving accumulation in mitochondria. The subsequently released Na+ in mitochondria not only contributed to the formation of mitomiR-494 induced G-quadruplexes for AIE imaging diagnosis but also led to an osmolarity surge that was enhanced by brequinar to achieve effective ion-interference therapy.

Quinaldine Red as a fluorescent probe for determining the melting temperature (Tm) of proteins: a simple, rapid and high-throughput assay

Proteins play an important role in biological systems and several proteins are used in diagnosis, therapy, food industry etc. Thus, knowledge about the physical properties of the proteins is of utmost importance, which will aid in understanding their function and subsequent applications. The melting temperature (Tm) of a protein is one of the essential parameters which gives information about the stability of a protein under different conditions. In the present study, we have demonstrated a method for determining the Tm of proteins using the supramolecular interaction between Quinaldine Red (QR) and proteins. Using this method, we have determined the Tm of 5 proteins and compared our results with established protocols. Our results showed good agreement with the other methods and published values. The method developed in this study is inexpensive, quick, and devoid of complex instruments and pre/post-treatment of the samples. In addition, this method can be adopted for high throughput in multi-plate mode. Thus, this study projects a new methodology for Tm determination of various proteins with user friendly operation.

Toxicity of a Quinaldine-Based Liquid Organic Hydrogen Carrier (LOHC) System toward Soil Organisms Arthrobacter globiformis and Folsomia candida

The study aims to establish a preliminary environmental assessment of a quinaldine-based LOHC system composed of hydrogen-lean, partially hydrogenated, and fully hydrogenated forms. We examined their toxicity toward the soil bacteria Arthrobacter globiformis and the Collembola Folsomia candida in two exposure scenarios, with and without soil, to address differences in the bioavailability of the compounds. In both scenarios, no or only slight toxicity toward soil bacteria was observed at the highest test concentration (EC₅₀ > 3397 μmol L^-1 and >4892 μmol kg^-1 dry weight soil). The effects of the three quinaldines on F. candida in soil were similar, with EC₅₀ values ranging from 2119 to 2559 μmol kg^-1 dry weight soil based on nominal concentrations. Additionally, corrected pore-water-concentration-based EC₅₀ values were calculated by equilibrium partitioning using soil/pore-water distribution coefficients. The tests without soil (simulating pore-water exposure) revealed higher toxicity, with LC₅₀ values between 78.3 and 161.6 μmol L^-1 and deformation of the protective cuticle. These results assign the compounds to the category "harmful to soil organisms". Potential risks toward the soil environment of the test compounds are discussed on the basis of predicted no-effect concentrations.

Separation and preconcentration of aluminum in parenteral solutions and bottled mineral water using different analytical techniques

A new method is reported for the separation of aluminum ions [Al(III)] from interfering elements in parenteral and pharmaceutical solutions (PS) and bottled mineral water (BMW) samples, through solid-phase extraction with 2-methyl-8-hydroxyquinoline (quinaldine) adsorbed onto activated silica gel. While the enrichment step of separated Al(III) was carried out by cloud point extraction (CPE) using 8-hydroxyquinoline as complexing reagent, the resulted complex was entrapped in a non-ionic surfactant octylphenoxypolyethoxyethanol (Triton X-114). The enriched Al(III) in sample solutions were determined by spectrofluorometry (SPF) at lambda(excitation) 370 nm and lambda(emission) 510 nm, and flame atomic absorption spectrometry (FAAS) for comparative purpose. The variables affecting the complexation and extraction steps were studied and optimized. The validity of methodology was checked with certified reference material of water and standard addition method. The enrichment factor and detection limit of Al(III) for the preconcentration of 50 ml of PS and BMW were found to be 100 and 0.25 microg/L, respectively. The proposed method has been applied for the determination of trace amount of Al(III) in PS and BMW samples with satisfactory results. In PS the levels of Al(III) are above than permissible limit (25 microg/L).

Fluorescent probing of the ligand-binding ability of blood plasma in the acute-phase response

The acute-phase response alters the composition of carrier proteins in plasma, which may affect the blood deposition and transport of biomediators and drugs. The effect of the acute-phase response on the ligand binding ability of plasma was studied in leukemic children with and without systemic inflammation (sepsis and septic shock). To target different transport proteins, differentially charged fluorescent dyes were used: anionic ANS (8-anilinonaphthalene-1-sulfonate), uncharged Nile red, and cationic Quinaldine red. Human serum albumin was a principal carrier for ANS and competed for Nile red binding with lipoproteins. The synchro-scan fluorescence spectra of Nile red in plasma distinguished two species of the dye bound to serum albumin and to low-density and/or very low-density lipoproteins. The binding of Quinaldine red did not correlate with albumin and lipoprotein levels, and was probably determined by alpha(1)-acid glycoprotein. Compared with the control group, leukemia increased Quinaldine red binding by 65% and did not significantly affect the binding of other probes. Sepsis and septic shock did not change the binding of Quinaldine red, but progressively decreased ANS binding, finally by about 33%, and shifted Nile red distribution from serum albumin toward lipoproteins. These changes reflected a modified composition of the three principal transport proteins in plasma in the acute-phase response. Simple and rapid fluorescent tests developed in this study can be used to evaluate the acute-phase response and to optimize drug administration protocols in clinical practice.

The antibacterial activity of new derivatives of 4-aminoquinoline and 4-aminoquinaldine

Two new series of N-alkyl derivatives of 4-aminoquinoline and 4-aminoquinaldine are described. Compounds in both series show antibacterial and protein precipitating properties and it has been possible to correlate bactericidal action and protein precipitation for homologous members of the series. The bacteriostatic activity of both series of compounds is characterised by maxima at C = 12 to 14, with a marked decrease in potency at longer chain lengths. The bactericidal activity differs from this in that activity is not greatly diminished with the higher homologues. The 4-aminoquinaldinium salts are slightly more potent bactericidal agents than the corresponding 4-aminoquinolinium compounds. It is concluded that the mechanism of the antibacterial action of these derivatives may be closely related to the means by which they interact with proteins

Modified electrodes with synthetic biocatalytic membranes

A biocatalytic membrane based on an immobilized enzyme molecule has been prepared. Oxidative electropolymerization of 8-hydroxyquinaldine (8-OHQ) monomers in 0.2 M, pH 7 phosphate buffer containing glucose oxidase (GOx) has been carried out to modify the surfaces of GC, Au, and Pt rotating disk electrodes. The biocatalytic properties of the synthesized membrane were characterized by studying the catalytic activities of the immobilized GOx. Signals obtained from modified GC electrodes with this biomembrane were mainly attributed to the immobilized GOx. Signals obtained from modified Pt or Au electrodes were due to the combined contribution of the enzyme and the native electrode's material. The potential analytical applications of these modified electrodes as bioelectrochemical sensors were also investigated.

A simple and rapid fluorometric determination method of alpha 1-acid glycoprotein in serum using quinaldine red

We examined different fluorescent probes suitable for fluorometric determination of alpha 1-acid glycoprotein (AGP) in serum. Quinaldine red (QR) was shown to bind strongly and selectively to AGP. Taking advantage of the enhanced fluorescence of QR in the presence of AGP, we developed a direct method for the determination of serum AGP without removal of other serum proteins such as albumin. AGP concentrations in serum of healthy volunteers and patients correlated well with results from the conventional single radial immunodiffusion (SRID) method (r = 0.93, slope = 1). The newly developed method is faster and has a larger analytical concentration range than the SRID method. This method can also be used to determine AGP in serum of experimental animals, and it can serve to monitor AGP serum concentrations for pharmacokinetic evaluation of basic drugs.

A resonance Raman and electronic absorption probe of membrane energization. Quinaldine red in cells of Streptococcus faecalis

Resonance Raman and electronic absorption spectra were used to show that the state of an amphiphilic cation, relative to dilute aqueous solution, changes when it is accumulated by cells of Streptococcus faecalis when they are energized. The general characteristics of the cation employed, quinaldine red, closely paralleled those of other amphiphilic cations which have been used to measure membrane potential. A major aspect of the change is that in sodium-loaded cells, essentially all of the quinaldine red accumulated as the result of energization forms a strong bond with an anionic group. This binding is similar to that which occurs for the basal level of quinaldine red taken up in nonenergized cells. Ionic binding was detected using resonance Raman spectroscopy through shifts associated with a N+ parallel C--C parallel C stretching vibration to lower frequency on uptake. Another aspect of the change in state is that the cell-localized probe cation can aggregate while ionically bonded in a card pack fashion, the transition dipoles being parallel. A combination of resonance Raman and electronic absorption spectroscopy was used to characterize this aggregation. The aggregates were estimated to contain at least five quinaldine red cations at or near van der Waals contact, and the presence of other molecules, such as phospholipids, could not be excluded. Aggregation effects are complex depending on the ratio of cells to probe cation, and on energization. The site of binding is suggested to be the lipid bilayer region of the plasma membrane on the basis of experiments with liposomes and other model systems. In addition, some quinaldine red may be present in the cytoplasm in an aggregated, ionically bound form. The change in state on uptake following energization seems to be associated with a membrane potential, similar spectral and uptake effects being produced by an artificially generated membrane potential in cells and liposomes. The results show that membrane potential cannot be computed in a simple manner from the distribution of quinaldine red between cells and medium, assuming that the thermodynamic activity coefficient of cell-localized material is identical with that in dilute aqueous solution. However, uptake as well as subsequent ionic binding of quinaldine red seems to be related to potential in an as yet undefined manner.

An interpretation of the three line EPR spectrum of nitric oxide hemeproteins and related model systems: the effect of the heme environment

The EPR spectra of the nitric oxide (NO) derivatives of structurally perturbed Fe (II) hemeproteins show various patterns, all of which are characterized by the conspicuous three-line hyperfine splitting due to 14NO, in contrast to that of the native proteins. For the purpose of obtaining structural information from these three line spectra, the model systems were studied, which consist of NO, heme (or TPP-Fe(II), where TTP means alpha, beta, gamma, delta-tetraphenylporphine) and the nitrogenous base, pyridine or quinoline, which, respectively, give the native type or the three line (perturbed type) EPR spectrum. The ring proton paramagnetic shift of quinoline in this system shows that it is not coordinated to NO-TPP-Fe(II) as a normal axial ligand, in contrast to pyridine which gives the shift pattern of the ordinary axial ligation. This observation suggests that in the NO-hemeproteins some perturbations of the protein structure cause the rupture or distortion of the bond between the imidazole nitrogen on the fifth coordination site and the heme iron, resulting in the three line spectrum. The EPR study of the model systems, the pentacoordinated complex, NO-heme and NO-TPP-Fe(II), in various media revealed that the pentacoordinated species indeed exhibits, depending upon its environment, a variety of spectra, which closely reproduce the three line patterns observed in the perturbed proteins and some related model systems. Such spectral variation can be attributed to the difference in the degree of quenching the internal motion and/or the structural heterogeneity caused by molecular environment.