Thermodynamic Study of Iodocyanopindolol β-Adrenoceptors Interactions with Rat Lung and Cerebral Cortex

Abstract

(±)¹²⁵ I-cyanopindolol (±) I CYP) was used to characterize β-adrenoceptors on rat lung and cerebral cortex membranes. The affinity of (±) ICYP was higher for lung (K^d = 64.3 pM) at 37°C. The association reaction of (±) ICYP was faster with lung (k₊₁ = 1.52 × 10⁹ M^?1.min^?1) than with cerebral cortex β-adrenoceptors (k₊₁ = 1.75 × 10⁸ M^?1.min^?1). In both tissues, the dissociation reaction followed a biphasic process with a fast (t ½ = 15.4 min and 5.6 min for lung and cerebral cortex respectively) and a slow component (t ½ = 474 min and 255 min for lung and cerebral cortex respectively). The thermodynamic parameters for (±) ICYP - β-adrenoceptors binding have been determined from kinetics and equilibrium studies, for the two tissues, at several temperatures between 0° and 44° C. For lung and cerebral cortex, Arrhenius plots were linear with different energies of activation. Van't Hoff plot was not linear for lung and the standard enthalpy and entropy changes of (±) ICYP - β-adrenoceptors interaction decreased linearly with temperature : the binding occured with a negative heat capacity change (ΔCp° = -368.9 cal. moles^?1. K^?1) at 25° C. Thermodynamic and kinetic results show that binding of (±) ICYP to lung β-adrenoceptors could involve two successive equilibria with a conformational change of the β-adrenergic receptor.     

A Water-Soluble Inclusion Complex of Pedunculoside with the Polymer β-Cyclodextrin: A Novel Anti-Inflammation Agent with Low Toxicity

More than 50% of new drug candidates in drug discovery are lipophilic and exhibit poor aqueous solubility, which results in poor bioavailability and a lack of dose proportionality. Here, we improved the solubility of pedunculoside (PE) by generating a water-soluble inclusion complex composed of PE and the polymer β-cyclodextrin (CDP). We characterized this novel complex by ¹H NMR, FT-IR, UV-vis spectroscopy, powder X-ray diffractometry and thermogravimetric analysis. The ratio of β-cyclodextrin (β-CD) units in CDP to PE was determined to be 2∶1. The K _D value of the inclusion complex was determined to be 4.29×10⁻³ mol•L⁻¹. In contrast to the low solubility of PE, the water-solubility of the PE–CDP complex was greatly enhanced. A preclinical toxicological study indicated that PE–CDP was well tolerated for a single administration. Importantly, the anti-inflammation potency of the PE–CDP complex was higher than that of PE. As a result, the formation of inclusion complexes by water-soluble CDP opens up possible aqueous applications of insoluble drug candidates in drug delivery.     

Study on the Interaction between the Inclusion Complex of Hematoxylin with β-Cyclodextrin and DNA

Ultraviolet-visible (UV-vis) spectra, fluorescence spectra, electrochemistry, and the thermodynamic method were used to discuss the interaction mode between the inclusion complex of hematoxylin with β-cyclodextrin and herring sperm DNA. On the condition of physiological pH, the result showed that hematoxylin and β-cyclodextrin formed an inclusion complex with binding ratio n_hematoxylin:n_{β-cyclodextrin} = 1:1. The interaction mode between β-cyclodextrin-hematoxylin and DNA was a mixed binding, which contained intercalation and electrostatic mode. The binding ratio between β-cyclodextrin-hematoxylin and DNA was n_{β-cyclodextrin -hematoxylin}:n_DNA = 2:1, binding constant was K^? _298.15K = 5.29 × 10⁴ L·mol^?1, and entropy worked as driven force in this action.     

Binding Interactions of Naringenin and Naringin with Calf Thymus DNA and the Role of β-Cyclodextrin in the Binding

The interaction of naringenin (Nar) and its neohesperidoside, naringin (Narn), with calf thymus deoxyribonucleic acid (ctDNA) in the absence and the presence of β-cyclodextrin (β-CD) was investigated. The interaction of Nar and Narn with β-CD/ctDNA was analyzed by using absorption, fluorescence, and molecular modeling techniques. Docking studies showed the existence of hydrogen bonding, electrostatic and phobic interaction of Nar and Narn with β-CD/DNA. 1:2 stoichiometric inclusion complexes were observed for Nar and Narn with β-CD. With the addition of ctDNA, Nar and Narn resulted into the fluorescence quenching phenomenon in the aqueous solution and β-CD solution. The binding constant K _b and the number of binding sites were found to be different for Nar and Narn bindings with DNA in aqueous and β-CD solution. The difference is attributed to the structural difference between Nar and Narn with neohesperidoside moiety present in Narn.     

Interactions of β-lactoglobulin with serotonin and arachidonyl serotonin

β‐Lactoglobulin (β‐LG) is a lipocalin, which is the major whey protein of cow's milk and the milk of other mammals. However, it is absent from human milk. The biological function of β‐LG is not clear, but its potential role in carrying fatty acids through the digestive tract has been suggested. β‐LG has been found in complexes with lipids such as butyric and oleic acids and has a high affinity for a wide variety of compounds. Serotonin (5‐hydroxytryptamine, 5‐HT), an important compound found in animals and plants, has various functions, including the regulation of mood, appetite, sleep, muscle contraction, and some cognitive functions such as memory and learning. In this study, the interaction of serotonin and one of its derivatives, arachidonyl serotonin (AA‐5HT), with β‐LG was investigated using circular dichroism (CD) and fluorescence intensity measurements. These two ligands interact with β‐LG forming equimolar complexes. The binding constant for the serotonin/β‐LG interaction is between 10⁵ and 10⁶ M⁻¹, whereas for the AA‐5HT/β‐LG complex it is between 10⁴ and 10⁵ M⁻¹ as determined by measurements of either protein or ligand fluorescence. The observed binding affinities were higher in hydroethanolic media (25% EtOH). The interactions between serotonin/β‐LG and AA‐5HT/β‐LG may compete with self‐association (micellization) of both the ligand and the protein. According to far‐ and near‐UV CD results, these ligands have no apparent influence on β‐LG secondary structure, however they partially destabilize its tertiary structure. Their binding by β‐LG may be one of the peripheral mechanisms of the regulation of the content of serotonin and its derivatives in the bowel of milk‐fed animals. © 2011 Wiley Periodicals, Inc. Biopolymers 95: 871–880, 2011.     

Quantitative Structure–Activity Relationship Study of 5-Iodo- and Diaryl-analogues of Tubercidin: Inhibitors of Adenosine Kinase

The adenosine kinase inhibitory (AKI) activity of 5-iodo and diaryl analogues of tubercidin is quantitatively analyzed using Fujita-Ban and Hansch type analyses. The Fujita-Ban analysis being a non-parametric approach assigned the highest contribution to Cl at the X-position, C6H4-4-Cl, C6H5, 2-furanyl and I at the Y-position and CH2NH2 and CH3 at the Z-position. In addition, a OH substituent at the C-position also emerged as a better choice possibly due to its engagement in hydrogen bonding with some active site function. Thus a compound having Cl, C6H4-4-Cl, CH2NH2 and OH respectively at X-, Y-, Z- and C-positions is predicted to have a potency nearly 1.5 orders of magnitude higher than the most potent compound of the parent data set. The Hansch type analysis, on the other hand, is a parametric approach and is carried out on two sub-sets of original compounds. This sub-division is based on size and nature of the substituents present at the X- and Y-positions. For the compounds in the first sub-set the derived significant correlation equation suggested that the substituent at the Y-position exhibiting a higher field effect and a substituent such as Cl and CH2NH2 at X- and Z-positions, respectively, are important for a compound to show increased AKI activity. Thio/alkylthio at X and CH2OCH3 at Z, on the other hand, lead to a detrimental effect. Similarly for the compounds in the second sub-set, the derived significant correlation equation showed that a substituent at the X-position having a higher negative field effect, a substituent at the Y-position having bulky groups and the C-position occupied by a OH group are essential for enhancement of the activity of a compound.     

Complex of Rutin with β-Cyclodextrin as Potential Delivery System

This study aimed to obtain and characterize an RU-β-CD complex in the context of investigating the possibility of changes in the solubility, stability, antioxidative and microbiological activity as well as permeability of complexated rutin as against its free form. The formation of the RU-β-CD complex via a co-grinding technique was confirmed by using DSC, SEM, FT-IR and Raman spectroscopy, and its geometry was assessed through molecular modeling. It was found that the stability and solubility of the so-obtained complex were greater compared to the free form; however, a slight decrease was observed inits antibacterial potency. An examination of changes in the EPR spectra of thecomplex excluded any reducing effect of complexation on the antioxidative activity of rutin. Considering the prospect of preformulation studies involving RU-β-CD complexes, of significance is also the observed possibility of prolongedly releasing rutin from the complex at a constant level over along period of 20 h, and the fact that twice as much complexated rutin was able topermeate compared to its free form.     

A Quantitative Structure–Activity Relationship Study on a Series of Na+, K+-ATPase Inhibitors

A quantitative structure–activity relationship (QSAR) study has been made on a new series of digitalis-like Na⁺,K⁺-ATPase inhibitors in which the guanylhydrazone group has been replaced by an aminoalkyloxime group. The correlations obtained have shown that the oxime moiety, primary amine group, overall size, and polarizability of the new type of substituents are higly beneficial to the Na⁺,K⁺-ATPase inhibition potency of the compounds and that their effect can be quantitatively assessed. The study also showed that the inotropic activity of the compounds is very well correlated with their Na⁺,K⁺-ATPase inhibition potency.     

Regulation of Properties of Lipid Membranes by Interaction with 2-Hydroxypropyl β-Cyclodextrin: Molecular Details

Russian Journal of Bioorganic Chemistry - The interaction between 2-hydroxypropyl β-cyclodextrin (HPCD) and a liposomal bilayer has been studied. The main binding sites of HPCD on the surface...     

Behavioral profile of ψ-MSH: Relationship with acta and β-endorphin action

In view of the close structural similarity of the pro-opiocortin fragment γ-MSH and of ACTH/MSH type peptides, the behavioral profile of γ-MSH was explored. Attention was first focussed on behavioral procedures in which ACTH/MSH related neuropeptides have been found effective. Using different procedures to test avoidance behavior, it was found that γ-MSH and ACTH-like neuropeptides had opposite effects. In this respect the activity of γ-MSH resembles that of opiate antagonists rather than that of β-endorphin. Accordingly, ACTH_1–24-induced excessive grooming which is blocked by opiate antagonists, is attenuated by γ-MSH. In addition, γ-MSH injected into the periaqueductal gray matter of the brainstem of opiate naive rats elicited symptoms reminiscent of those seen after opiate withdrawal. γ-MSH attenuated more or less several effects of intracerebroventricularly administered β-endorphin (e.g. antinociception, hypothermia, α-MSH release) and decreased acquisition of heroin self-administration. Although γ-MSH at rather high doses displaced naloxone from its specific binding sites in brain homogenates, it did not interfere with β-endorphin-induced effects on in vitro muscle preparations (guinea pig ileum, rat rectum). Interestingly, γ-MSH induced relaxation of the rat rectum in vitro. It is postulated that γ-MSH may attenuate β-endorphin-induced effects by acting via γ-MSH receptor sites (functional antagonism), although a pharmacological antagonism cannot be excluded as yet.     

Quantitative Study of Anomeric Forms of Maltose Produced by α- and βAmylases

Anomeric forms of glucose and maltose produced from phenyl, p-nitrophenyl, p-tert-butylphenyl, p-ethylphenyl and p-chlorophenyl α-maltosides and maltopentaose by α- and β-amylases were determined quantitatively by a gas-liquid chromatographic method. All of the three kinds of α-amylases tested, B. subtilis saccharifying α-amylase, Taka-amylase A, and porcine pancreas α-amylase, were found to produce only α-maltose from the maltosides. Sweet potato and barley β-amylases produced β-maltose from maltopentaose.

Saccharifying α-amylase from B. subtilis also released α-maltose from all the maltosides mentioned above, contrary to the report by Shibaoka et al. that the enzyme released β-maltose from maltosides other than phenyl α-maltoside: FEBS Lett., 16, 33 (1971); J. Biochem., 77, 1215 (1975). It appears unlikely that the α-amylase releases β-maltose, depending on the kind of substrate.     

Quantifying Interactions of β-Synuclein and γ-Synuclein with Model Membranes

The synucleins are a family of proteins involved in numerous neurodegenerative pathologies [α-synuclein and β-synuclein (βS)], as well as in various types of cancers [γ-synuclein (γS)]. While the connection between α-synuclein and Parkinson's disease is well established, recent evidence links point mutants of βS to dementia with Lewy bodies. Overexpression of γS has been associated with enhanced metastasis and cancer drug resistance. Despite their prevalence in such a variety of diseases, the native functions of the synucleins remain unclear. They have a lipid-binding motif in their N-terminal region, which suggests interactions with biological membranes in vivo. In this study, we used fluorescence correlation spectroscopy to monitor the binding properties of βS and γS to model membranes and to determine the free energy of the interactions. Our results show that the interactions are most strongly affected by the presence of both anionic lipids and bilayer curvature, while membrane fluidity plays a very minor role. Quantifying the lipid-binding properties of βS and γS provides additional insights into the underlying factors governing the protein-membrane interactions. Such insights not only are relevant to the native functions of these proteins but also highlight their contributions to pathological conditions that are either mediated or characterized by perturbations of these interactions.     

Interactions of Alkylphosphocholines with Model Membranes—The Langmuir Monolayer Study

Alkylphosphocholines (APCs) belong to a class of synthetic antitumor lipids, which are new-generation anticancer agents. In contrast to traditional antitumor drugs, they do not attack the cell nucleus but, rather, the cellular membrane; however, their mechanism of action is not fully understood. This work compared the interactions of selected APCs [namely, hexadecylphosphocholine (miltefosine), octadecylphosphocholine and erucylphosphocholine] with the most important membrane lipids [cholesterol, 1,2-dipalmitoyl-sn-glycero-3-phosphocholine (DPPC) and 1-palmitoyl-2-oleoyl-sn-glycero-3-phosphocholine (POPC)] and examined their influence on a model membrane of tumor and normal cells. As a simple model of membranes, Langmuir monolayers prepared by mixing cholesterol either with a saturated phosphatidylcholine (DPPC), for a normal cell membrane, or with an unsaturated one (POPC), for a tumor cell membrane, have been applied. The APC–lipid interactions, based on experimental surface pressure (π) versus mean molecular area (A) isotherms, were analyzed qualitatively (with mean molecular area values) as well as quantitatively (with the ΔG ^exc function). Strong attractive interactions were observed for mixtures of APCs with cholesterol, contrary to the investigated phosphatidylcholines, for which the interactions were found to be weak with a tendency to separation of film components. In ternary monolayers it has been found that the investigated model systems (cholesterol/DPPC/APC vs cholesterol/POPC/APC) differ significantly as regards the interactions between film-forming molecules. The results demonstrate stronger interactions between the components of cholesterol/POPC/APC monolayers compared to cholesterol/POPC film, mimicking tumor cell membranes. In contrast, the interactions in cholesterol/DPPC/APC films were found to be weaker than those in the cholesterol/DPPC system, serving as a model of healthy cell membranes, thus proving that the incorporation of APCs is, from a thermodynamic point of view, unfavorable for binary cholesterol/DPPC monolayers. It can be concluded that the composition of healthy cell membranes is a natural barrier preventing the incorporation of APCs into normal cells.     

Chemico-biological interaction of Etravirine and its β-Cyclodextrin complex with macromolecular targets

The interaction of etravirine with β-cyclodextrin is analyzed by UV–visible absorption, infrared, fluorescence, nuclear magnetic resonance, two-dimensional rotational frame nuclear Overhauser effect spectroscopy, and molecular modeling studies. The 4-hydroxy-3, 5-dimethylbenzonitrile moiety is found to take part in the binding. The stoichiometry of the inclusion complex of ET with β-CD is 1:1 with the binding constant of 2.03 × 10³ mol^?1 dm³. The binding of ET with calf thymus DNA (ctDNA) and bovine serum albumin (BSA) protein is investigated in the presence and the absence of β-CD. Fluorescence enhancement is observed during the binding of ET with ctDNA in the absence of β-CD, whereas in the presence of β-CD, fluorescence quenching is observed. The binding constants of the binding of ET and ET–β-CD to ctDNA are 7.84 × 10⁴ and 4.38 × 10⁴ mol^?1 dm³, respectively. The binding constant of the binding of ET and ET–β-CD to BSA are 3.14 × 10⁴ and 1.6396 × 10⁴ mol^?1 dm³, respectively. The apparent binding constants between ET–β-CD complex and ctDNA or BSA protein decreases significantly. The numbers of binding sites of interaction of ET with BSA protein and the binding distance between BSA protein and ET the absence and the presence of β-CD differ. β-CD modulates the binding of ET with the macromolecular targets.     

Young Children’s Drawings of Plant Life: A Study Concerning the Use of Colours and its Relationship with Age

This study examines the drawings that elementary grade school children make on the subject of plant life. More specifically, the pictorial elements drawn by children are analysed together with their colour choices and the size of coloured surfaces. Furthermore, the results are put into perspective with the age of the children in the sample. The results indicate that there are significant differences in terms of both the content of the drawings and how colours are used. These findings are linked to the process of the comprehension of the plant world that, according to several studies, initially begins in elementary education. The conclusions highlight the convenience of considering the study of young children’s drawings and colour choices in order to achieve a clearer picture regarding the initial steps of the process of the understanding of biological phenomena in early childhood.     

Study on the Interaction of β-Cyclodextrin and Berberine Hydrochloride and Its Analytical Application

The fluorescence enhancement of berberine hydrochloride (BBH) as a result of complex with β-cyclodextrin (β-CD) is investigated. The mechanism of the inclusion was studied and discussed by spectrofluoremetry and infrared spectrograms. The results showed that a 1∶1 (β-CD: BBH) complex was formed with an apparent association constant of 4.23×10² L/mol. Based on the enhancement of the fluorescent intensity of berberine hydrochloride, a new spectrofluorimetric method for the determination of BBH in the presence of β-CD was developed. The linear range was 1.00∼4.00 µg/mL with the detection limit of 5.54 ng/mL. The proposed method was successfully applied to the determination of BBH in tablets.     

Preparation of Aryl β-d-Mannopyranoside Derivatives via β-d-arabino-Hexopyranosiduloses

Sequential oxidation and reduction of aryl 4, 6-O-benzylidene-β-d-glucosides with dimethyl sulfoxide-phosphorus pentoxide mixture (DMSO–P₂O₅) and sodium borohydride were carried out as a new means for the preparation of aryl β-d-mannopyranoside derivatives. p-Nitrophenyl 4, 6-O-benzylidene-β-d-mannopyranoside was obtained in 22% yield from the corresponding glucoside 3-O-acetate, whereas from the unprotected acetal, 4, 6-O-benzylidene acetals of the corresponding mannoside and alloside were isolated in the yields of 6.7 and 2.1%, respectively. Similarly, phenyl 4, 6-O-benzylidene β-d-mannoside, alloside, and altroside were obtained from the corresponding glucoside in 2.2, 0.8 and 2.1% yields, respectively.     

Increasing Doxycycline Hyclate Photostability by Complexation with β-Cyclodextrin

Doxycycline hyclate (DOX) is a highly photosensitive drug, a feature that limits the stability of the corresponding dosage forms. The main objectives of this work were the preparation and characterization of an inclusion complex of DOX with β-cyclodextrin (βCD) and to investigate if this approach could improve the photostability of the drug. Guest-host interactions were investigated using nuclear magnetic resonance, which were afterwards combined with molecular modeling methods to study the complex formation and its three-dimensional structure was proposed. A freeze-drying method was applied to obtain the complex in the solid state, which was further confirmed by thermal and spectroscopic techniques. To evaluate the complexation effect on DOX integrity, the photostability of the inclusion complex was studied, with a significant decrease in the photodegradation of DOX being found in aqueous solution upon complexation. Finally, the photoprotection produced by the complexation was evaluated by means of an antimicrobial assay. Overall, the presented results suggest that the formulation of DOX complexed with βCD constitutes an interesting approach for the preparation of pharmaceutical dosage forms of DOX with enhanced stability properties.KEY WORDS: β-cyclodextrin, doxycycline hyclate, microbiological assay, molecular modeling, photostability     

Molecular Interactions of Alzheimer's Biomarker FDDNP with Aβ Peptide

All-atom explicit solvent model and replica exchange molecular dynamics were used to investigate binding of Alzheimer''s biomarker FDDNP to the Aβ_10–40 monomer. At low and high concentrations, FDDNP binds with high affinity to two sites in the Aβ_10–40 monomer located near the central hydrophobic cluster and in the C-terminal. Analysis of ligand- Aβ_10–40 interactions at both concentrations identifies hydrophobic effect as a main binding factor. However, with the increase in ligand concentration the interactions between FDDNP molecules also become important due to strong FDDNP self-aggregation propensity and few specific binding locations. As a result, FDDNP ligands partially penetrate the core of the Aβ_10–40 monomer, forming large self-aggregated clusters. Ligand self-aggregation does not affect hydrophobic interactions as a main binding factor or the location of binding sites in Aβ_10–40. Using the Aβ_10–40 conformational ensemble in ligand-free water as reference, we show that FDDNP induces minor changes in the Aβ_10–40 secondary structure at two ligand concentrations studied. At the same time, FDDNP significantly alters the peptide tertiary fold in a concentration-dependent manner by redistributing long-range, side-chain interactions. We argue that because FDDNP does not change Aβ_10–40 secondary structure, its antiaggregation effect is likely to be weak. Our study raises the possibility that FDDNP may serve as a biomarker of not only Aβ fibril species, but of monomers as well.