Transport of Tryptophan into Brain from the Circulating, Albumin-Bound Pool in Rats and in Rabbits

Tryptophan is the only amino acid in the circulation that is bound by albumin, and previous studies have suggested that the brain tryptophan supply is a function of either the free or the albumin-bound pool of tryptophan in blood. Since the albumin molecule per se does not cross the brain capillary wall, i.e., the blood-brain barrier (BBB), the transport of tryptophan from the circulating albumin-bound pool may involve enhanced dissociation of tryptophan from the albumin binding sites within the cerebral microcirculation. This hypothesis was confirmed in the present studies wherein the dissociation constant (KaD) of albumin binding of tryptophan in the rat or rabbit brain microcirculation was measured in vivo. Brain extraction data for [14C]tryptophan determined with the carotid artery injection technique were fit to the Kety-Renkin-Crone equation modified for protein-bound solute. The KaD of albumin binding in the rat or rabbit brain microcirculation under pentobarbital anesthesia was 1.7 +/- 0.1 and 3.9 +/- 1.0 mM, respectively, as compared to the KD value measured in vitro with equilibrium dialysis, 0.13 +/- 0.03 mM. In contrast, the KaD value of albumin binding of tryptophan in vivo in the rabbit brain microcirculation was reduced by ether anesthesia to a value of 2.1 +/- 0.4 mM. This reduction in the KaD under ether anesthesia was associated with a 2.5-fold increase in cerebral blood flow. In addition, dialyzed rabbit serum caused a statistically significant inhibition in [14C]tryptophan influx during ether, but not pentobarbital, anesthesia.(ABSTRACT TRUNCATED AT 250 WORDS)     

Ionic Strength Dependence of Calcium, Adenine Nucleotide, Magnesium, and Caffeine Actions on Ryanodine Receptors in Rat Brain

Abstract: [³H]Ryanodine binding studies of ryanodine receptors in brain membrane preparations typically require the presence of high salt concentrations in assay incubations to yield optimal levels of binding. Here, radioligand binding measurements on rat cerebral cortical tissues were conducted under high (1.0 M KCI) and low (200 mM KCI) salt buffer conditions to determine the effects of ionic strength on receptor binding properties as well as on modulation of ligand binding by Ca²⁺, Mg²⁺, β,γ-methylene-adenosine 5′-triphosphate (AMP-PCP), and caffeine. In 1.0 M KCI buffer, labeled titration/equilibrium analyses yielded two classes of binding sites with apparent K_D (nM) and B_max (fmol/mg of protein) values of 2.4 and 34, respectively, for the high-affinity site and 19.9 and 157, respectively, for the low-affinity site. Unlabeled titration/equilibrium measurements gave a single high-affinity site with a K_D value of 1.9 nM and a B_max value of 95 fmol/mg of protein. The apparent K_D value derived from association and dissociation studies was 20 pM. Equilibrium binding was activated by Ca²⁺ (K_D/Ca²⁺= 14 nM), inhibited by Mg²⁺ (IC₆₀= 5.0 mM), and unaffected by AMP-PCP or caffeine. In 200 mM KCI buffer conditions, labeled titration analyses gave only a single site with a K_D value similar to and a B_max value 1.8-fold greater than those obtained for the low-affinity site in 1.0 M KCI buffer. In unlabeled titration measurements, the K_D value was fivefold lower, whereas the B_max value was unaffected. The K_D value derived from association and dissociation analysis was 2.4-fold greater in 200 mM KCI compared with 1.0 M KCI buffer conditions. In 200 mM compared with 1.0 M KCI, the potency with which Mg²⁺ inhibited binding was increased by 3.8-fold, whereas the affinity of the activation site for Ca²⁺ was reduced by 13-fold. Addition of caffeine in the presence of low salt increased the affinity of Ca²⁺ activation by 1.7-fold. The inhibitory effect of Mg²⁺ on [³H]-ryanodine binding in the presence of 200 mM KCI was reversed by AMP-PCP and caffeine with apparent EC₅₀ values of 0.25 and 7.6 mM, respectively. Taken together, these results indicate that ionic strength is an important consideration in binding studies of brain ryanodine receptors and their interactions with modulatory agents.     

Effect of Age on Variables Influencing the Supply of Tryptophan to the Brain

Abstract: The relations of plasma concentrations of substances claimed to influence brain tryptophan concentration (total tryptophan, free tryptophan, large neutral amino acids) with the concentrations of tryptophan, 5-hydroxytryptamine (5-HT), and 5-hydroxyindoleacetic acid (5-HIAA) in the forebrain were investigated in rats of different ages (from 8 days to 16 months after birth). In brain, tryptophan fell by 46%, whereas 5-HT rose by 20% between 8 and 40/42 days after birth. Thereafter, the levels of both tryptophan and 5-HT remained essentially constant. Brain 5-HIAA showed a more complex pattern, rising by 63% between 8 and 19 days, falling between 19 and 40/42 days, and then gradually rising until values at 16 months were significantly higher than those at 40/42 days. In plasma, the concentrations of free fatty acids, free and total tryptophan, and large neutral amino acids all decreased between 8 and 19 days and thereafter either remained constant or increased slowly, the exception being total tryptophan values, which showed large increases between 28/30 and 60/70 days. Also, the unidirectional uptake of tryptophan from blood to brain was determined using a carotid artery injection technique. Uptake values obtained using a tracer concentration of tryptophan in the injection solution decreased progressively with age. Kinetic analysis of the data in terms of the Michaelis-Menten equation for carrier-mediated transport indicated significantly lower values for V_max and K_D (a component for nonsaturable transport) in 6-month-old rats as compared to 19-day-old suckling rats, whereas K_m values were the same at both ages. Detailed analysis of these results indicated that the age-related changes in brain tryptophan were largely explicable in terms of plasma free tryptophan in association with blood-brain transport characteristics; moderate differences in concentration of amino acids competing for transport were without apparent effect between 19 days and 16 months. The larger differences between 8 and 19 days after birth could be important.     

Isolation of plasma membrane and binding of the Ca2+ antagonist nimodipine in Chlamydomonas reinhardtii

Chlorophyll-free plasma membranes of the unicellular green alga Chlamydomonas reinhardtii Dangeard were purified from a microsomal fraction using an aqueous polymer two-phase system of 6.5% (w/w) dextran T500, 6·5% (w/w) polyethylene glycol 3350, 60 mM NaCI, 0 33 M sucrose and 5 mM potassium phosphate (pH 7·8). The plasma membrane fraction contained only 2·4% of the microsomal membrane protein. Specific activity of the plasma membrane marker enzyme, K*, Mg²⁺-ATPase (EC 3.6.1.3). was enriched 9-fold over the microsomal fraction, and 22% of total activity was recovered in the upper, polyethylene glycol-rich phase. Contamination from intracellular membranes was minimal. K*, Mg²⁺-ATPase showed a pH optimum at about 6·5, and addition of 0·05% (w/v) Triton X-100 stimulated the activity 3-fold. [³H]-Nimodipinc was employed to characterize 1,4-dihydropyridine-specific membrane receptors. Two apparent binding sites with different affinities to nimodipine were found in the crude microsomal fraction. The separation of plasma membranes from intracellular membranes revealed that one binding site with higher affinity (K_D= 9 nM) was located on the plasma membrane and a second binding site with lower affinity (K_D= 36 nM) on an intracellular membrane The apparent dissociation constants determined from the association and dissociation rate constants in kinetic experiments were comparable to those determined by equilibrium experiments. The maximum number of binding sites of the plasma membrane fraction and the intracellular membrane fraction was B_max= 440 and 470 fmol (mg protein)^-1, respectively. [³H]-Nimodipinc binding was inhibited by (±) verapamil and stimulated by D-cis-diltiazem in both fractions. Moreover, ethyle-neglycol-bis(2-aminoethylcther)-N, N'-tetraacctic acid (EGTA) inhibited [³H]-nimo-dipinc binding in the plasma membrane fraction but not in the intracellular membrane fraction This effect was cancelled by the addition of CaCl₂.     

Effect of albumin binding and amino acid competition on tryptophan uptake into brain.

Abstract— In the present study we examine the influence of pH, palmitate, and neutral amino acids on the passage of tryptophan from blood into brain during a single capillary pass, and on the partitioning of tryptophan between free and albumin-bound forms. The results show that a considerable fraction of albumin-bound tryptophan is stripped from albumin sites during passage, that uptake is concentration-dependent, and that amino acid competition for carrier sites is quantitatively the most important factor in regulating tryptophan uptake into brain. The interaction between tryptophan concentration, tryptophan binding, and competing amino acids is of considerable influence on brain serotonin biosynthesis.     

Resveratrol Binding to Human Serum Albumin

Abstract

Resveratrol (Res), a polyphenolic compound found largely in the skin of red grape and wine, exhibits a wide range of pharmaceutical properties and plays a role in prevention of human cardiovascular diseases [Pendurthi et al., Arterioscler. Thromb. Vasc. Biol. 19, 419–426 (1999)]. It shows a strong affinity towards protein binding and used as inhibitor for cyclo- oxygenase and ribonuclease reductase. The aim of this study was to examine the interaction of resveratrol with human serum albumin (HSA) in aqueous solution at physiological conditions, using a constant protein concentration (0.3 mM) and various pigment contents μM to mM). FTIR, UV-Visible, CD, and fluorescence spectroscopic methods were used to determine the resveratrol binding mode, the binding constant and the effects of pigment complexation on protein secondary structure.

Structural analysis showed that resveratrol bind non-specifically (H-bonding) via polypeptide polar groups with overall binding constant of K_Res = 2.56× 10⁵ M^?1. The protein secondary structure, analysed by CD spectroscopy, showed no major alterations at low resveratrol concentrations (0.125 mM), whereas at high pigment content (1 mM), major increase of α-helix from 57% (free HSA) to 62% and a decrease of β-sheet from 10% (free HSA) to 7% occurred in the resveratrol-HSA complexes. The results indicate a partial stabilization of protein secondary structure at high resveratrol content.     

Chimeric peptides as a vehicle for peptide pharmaceutical delivery through the blood-brain barrier

A new strategy for peptide delivery through the brain capillary wall, i.e., the blood-brain barrier (BBB), is the synthesis of chimeric peptides which are formed by the covalent coupling of a non-transportable peptide (e.g., beta-endorphin) to a transportable peptide that undergoes receptor- or absorptive-mediated transcytosis at the BBB. beta-endorphin was covalently coupled via disulfide linkage to cationized albumin (pI greater than or equal to 9) which, owing to it's highly basic charge, undergoes rapid absorptive-mediated transport into brain from blood. The [3H]labeled beta-endorphin-cationized albumin chimera was rapidly taken up by isolated brain capillaries in vitro and by rat brain in vivo; conversely, the BBB uptake of native [3H]beta-endorphin was negligible. The synthesis of chimeric peptides is a new strategy for solving the problem of peptide delivery through the BBB.     

Interaction of the dye Remazol Yellow GGL to prealbumin and albumin studied by affinity phase partition,difference spectroscopy and equilibrium dialysis

In partition experiments in aqueous two-phase systems composed of 10% (w/w) dextran (M_r=500000) and 7.510 (w/w) poly(ethylene-glycol) (M_r=6000) prealbumin and albumin are directed into the dextran-rich phase. Addition of Remazol Yellow GGL covalently bound to poly(ethylene-glycol) causes a transfer of prealbumin and albumin into the poly(ethylene-glycol)-rich phase. This indicates an interaction of both proteins with the dye (affinity phase partitioning).The affinity partitioning effect on prealbumin is markedly increased by an excess of monomeric albumin. This points to an interaction of the two proteins in the presence of the dye.Binding of free Remazol Yellow GGL to prealbumin and albumin was investigated by means of equilibrium dialysis and difference spectroscopy. In respect to prealbumin equilibrium dialysis resulted in the binding of four molecules of the dye to two classes of binding sites with dissociation constants of K_H=3.3 IM and K_L=258 µM respectively whereas albumin was found to bind eight molecules of the dye to two classes of binding sites with K_H=5.8 µM and K_L=282 µM. Similar binding stoichiometries were found by difference spectroscopy.By application of difference spectroscopy and affinity phase partitioning thyroxine and triiodothyronine known as natural ligands of prealbumin and albumin were found to compete with Remazol Yellow GGL for the dye binding sites of the proteins.     

Insulin binding and glucose transport in the R3230AC mammary adenocarcinoma

Cells dissociated from the R3230AC mammary adenocarcinoma from intact and diabetic rats were examined for insulin binding and glucose transport. The K_d for insulin binding, ～ 10^?10 M, was similar in all tumors studied. However, the apparent number of receptor sites per cell increased in cells from diabetic rats. Kinetic analysis of 3-0-methyl glucose (3-OMG) entry showed both diffusional and passive carrier characteristics. Insulin (4 × 10^?9 M) in vitro did not affect diffusional entry, whereas the hormone altered the passive carrier system, as reflected by an increase in K_m and V_max. Insulin decreased initial velocity of glucose transport at 4–6 mM glucose levels but increased initial velocity of glucose transport at 20 mM glucose. An explanation of the role of insulin on tumor growth in vivo from effects on glucose transport in vitro is proposed.     

Effects of Albumin, Amino Acids and Clofibrate on the Uptake of Tryptophan by the Rat Brain

Abstract: The influences of total tryptophan concentration, albumin binding and amino acid competition on the rate of tryptophan influx into rat brain were compared using a single-pass injection technique with tritiated water as a freely diffusible reference. Omission of 3% bovine albumin from a bolus containing tryptophan in Krebs–Ringer bicarbonate buffer injected into the carotid artery increased non-albumin bound (free) tryptophan concentration threefold but tryptophan uptake by only 35% and 30% into forebrain and hypothalamus, respectively. However, tryptophan uptake from injected rat plasma was more markedly elevated when free tryptophan concentration was raised. Thus, when free tryptophan was doubled, but total tryptophan unchanged, by in vitro addition of clofibrate to a plasma bolus, uptake was increased by 53% and 28% into forebrain and hypothalamus respectively. When clofibrate was injected in vivo so that plasma total tryptophan concentration was decreased by 45% but neither free tryptophan nor competing amino acid concentrations were altered, then uptake from a bolus of the rat's own plasma was unchanged. Addition of competing amino acids at physiological concentrations to tryptophan in Krebs-Ringer buffer significantly reduced tryptophan influx into both brain regions, but did not increase the effect of albumin binding. The results indicate that tryptophan uptake into rat forebrain is substantially influenced by albumin binding and competition from other amino acids, but that hypothalamic uptake is less influenced by these factors.     

Steroid hormonal regulation of calcium-binding protein regucalcin mRNA expression in the kidney cortex of rats

Ethylenediamine tetraacetate ( EDTA ) inhibits lactoperoxidase (LPO)-catalyzed rate of iodide oxidation in concentration and pH-dependent manner. A plot of log Ki_app values against various pH yields a sigmoidal curve from which an ionisable group of pK_a value 6.0 could be ascertained for controlling the inhibition of catalytically active LPO by EDTA. Kinetic studies indicate that EDTA competitively inhibits iodide oxidation by acting as an electron donor. EDTA al so reduces LPO-compound-11 to the native ferric state by one-electron transfer as evidenced by the spectral shift from 428 to 412 nm. Optical difference spectroscopic studies indicate that EDTA binds to LPO with the apparent equilibrium dissociation constant (KD) of 12 ± 2 mM at pH 6.5. A plot of log K_D values against various pH produces a sigmoidal curve from which an ionisable group of LPO having pk_a = 5.47 could be calculated, deprotonation of which favours EDTA binding. EDTA also binds to LPO-CN- complex indicating its binding site away from heme iron centre. The K_D of LPO-EDTA complex is significantly increased (62 ± 5 mM) by iodide suggesting that EDTA binds close to the iodide binding site. EDTA also increases the K_D value of LPO-hydroquinone complex from 62 ± 5 mM to 200 ± 21 mM indicating that EDTA and aromatic donor binding sites are also close. We suggest that EDTA inhibits iodide oxidation competitively as an electron donor by interacting at or near the iodide binding site and these sites are close to the aromatic donor binding site.     

Magnesium reduces affinities of antagonists at rat cortex α2-adrenergic receptors labeled with 3H-clonidine: Evidence for heterogeneity of α2-receptor conformations with respect to antagonists

³H-clonidine labeled two binding sites in rat cortex membranes with apparent K_D values of about 1.0 and 5.9 nM. These sites appeared analogous to “super-high” (SH) and “high” (H) affinity states of the α₂-receptor described in human platelets. 10 mM magnesium increased the number of SH receptors by 30% whereas 100 μM GTP reduced SH₃receptor number by 45% with no significant change in the K_D of ³H-clonidine at α₂(SH) sites. In drug competition studies using 1.0 nM ³H-clonidine, 100 μM GTP reduced the affinity of clonidine and increased the affinity of yohimbine, whereas 10 mM magnesium increased the affinity of clonidine and reduced the affinity of yohimbine. The effect of magnesium on the affinity of several antagonists at cortex ³H-clonidine sites ranged from none (phentolamine) to a 6-fold reduction (piperoxan). These data indicate that different states of the α₂-receptor exhibit different affinities for some antagonists.     

Tryptophan residue is essential for immunoreactivity of a diagnostically relevant peptide epitope of A. fumigatus

The role of tryptophan (Trp¹⁷) in immunoreactivity of P1, the diagnostically relevant peptide from a major allergen/antigen of Aspergillus fumigatus, was evaluated by chemically modifying tryptophanyl residue of P1. In BIAcore kinetic studies, unmodified P1 showed a 100-fold higher binding with ABPA (Allergic Bronchopulmonary Aspergillosis) patients’ IgG [K_D (equilibrium dissociation constant) = 2.74 e⁻⁸ ± 0.13 M] than the controls’ IgG (K_D = 2.97 e⁻⁶± 0.14 M), whereas chemically-modified P1 showed similar binding [K_D patients’ IgG = 3.25 e⁻⁷± 0.16 M, K_D controls’ IgG = 3.86 e⁻⁷± 0.19 M] indicating loss of specific immunoreactivity of P1 on tryptophan modification. Modified P1 showed loss of specific binding to IgE and IgG antibodies of ABPA patients in ELISA (Enzyme-Linked Immunosorbent Assay). The study infers that tryptophan residue (Trp¹⁷) is essential for immunoreactivity of P1.     

Isolated cardiac myocytes A new cellular model for studying insulin modulation of monosaccharide transport

The usefulness of isolated Ca²⁺-tolerant myocytes as a cellular model system for investigating modulation of monosaccharide transport by insulin was investigated. We have found that the isolation technique described by Haworth et al. (Haworth, R.A., Hunter, D.R. and Berkoff, H.A. (1980) J. Mol. Cell. Cardiol. 12, 715–724), with some minor modifications, consistently gave the highest yield of quiescent, rod-shaped myocytes which maintained their integrity in the presence of 2 mM calcium. Using 3-O-methylglucose, a non-metabolized sugar, transport was shown to possess saturability, substrate stereospecificity, competition and countertransport; all of which have been thoroughly established for d-glucose transport in other systems. The apparent K_m of transport ranged from 2.3 to 3.5 mM. Insulin (10 nM) caused a small but significant increase in K_m and a 2–3-fold increase in V_max. These results suggest that this myocyte preparation will provide a useful model for studying the transport-related effects of insulin as well as current hypotheses regarding the mechanism of insulin modulation of transport at the cellular level.     

Aryl acylamidase activity of human serum albumin with o-nitrotrifluoroacetanilide as the substrate

Albumin is generally regarded as an inert protein with no enzyme activity. However, albumin has esterase activity as well as aryl acylamidase activity. A new acetanilide substrate, o-nitrotrifluoroacetanilide (o-NTFNAC), which is more reactive than the classical o-nitroacetanilide, made it possible to determine the catalytic parameters for hydrolysis by fatty-acid free human serum albumin. Owing to the low enzymatic activity of albumin, kinetic studies were performed at high albumin concentration (0.075 mM). The albumin behavior with this substrate was Michaelis-Menten like. Kinetic analysis was performed according to the formalism used for catalysis at high enzyme concentration. This approach provided values for the turnover and dissociation constant of the albumin-substrate complex: k_cat = 0.13 ± 0.02 min ? ¹ and K_s = 0.67 ± 0.04 mM. MALDI-TOF experiments showed that unlike the ester substrate p-nitrophenyl acetate, o-NTFNAC does not form a stable adduct (acetylated enzyme). Kinetic analysis and MALDI-TOF experiments demonstrated that hydrolysis of o-NTFNAC by albumin is fully rate-limited by the acylation step (k_cat = k₂). Though the aryl acylamidase activity of albumin is low (k_cat/K_s = 195 M^{? 1}min^{? 1}), because of its high concentration in human plasma (0.6–1 mM), albumin may participate in hydrolysis of aryl acylamides through second-order kinetics. This suggests that albumin may have a role in the metabolism of endogenous and exogenous aromatic amides, including drugs and xenobiotics.     

Kinetics of Na+, K+-ATPase Inhibition by a Rat Brain Endogenous Factor (II-E)

Previous work from this laboratory led to the isolation by gel filtration and anionic exchange HPLC of a rat brain fraction named II-E, which highly inhibits synaptosomal membrane Na⁺, K⁺-ATPase activity. In this study we evaluated the kinetics of such inhibition and found that inhibitory potency was independent of Na⁺(1.56–200 mM), K⁺(1.25–40 mM), or ATP (1–8 mM) concentration. Hanes-Woolf plots indicated that II-E decreases Vmax but does not alter K_Mvalue, and suggested uncompetitive inhibition for Na⁺, K⁺or ATP. However, II-E became a stimulator at 0.5 mM ATP concentration. It is postulated that this brain factor may modulate ionic transport at synapses, thus participating in central neurotransmission.     

Binding to the high-affinity substrate site of the (Na+ + K+)-dependent ATPase

The (Na⁺ + K⁺)-dependent ATPase exhibits substrate sites with both high affinity (K _m near 1 µM) and low affinity (K _m near 0.1 mM) for ATP. To permit the study of nucleotide binding to the high-affinity substrate sites of a canine kidney enzyme preparation in the presence as well as absence of MgCl₂, the nonhydrolyzable - imido analog of ATP, AMP-PNP, was used in experiments performed at 0–4°C by a centrifugation technique. By this method theK _D for AMP-PNP was 4.2 µM in the absence of MgCl₂. Adding 50 µM MgCl₂, however, decreased theK _D to 2.2 µM; by contrast, higher concentrations of MgCl₂ increased theK _D until, with 2 mM MgCl₂, theK _D was 6 µM. The half-maximal effect of MgCl₂ on increasing theK _D occurred at approximately 1 mM. This biphasic effect of MgCl₂ is interpreted as Mg²⁺ in low concentrations favoring AMP-PNP binding through formation at the high-affinity substrate sites of a ternary enzyme-AMP-PNP-Mg complex; inhibition of nucleotide binding at higher MgCl₂ concentrations would represent Mg²⁺ acting through the low-affinity substrate sites. NaCl in the absence of MgCl₂ increased AMP-PNP binding, with a half-maximal effect near 0.3 mM; in the presence of MgCl₂, however, NaCl increased theK _D for AMP-PNP. KCl decreased AMP-PNP binding in the presence or absence of MgCl₂, but the simultaneous presence of a molar excess of NaCl abolished (or masked) the effect of KCl. ADP and ATP acted as competitors to the binding of AMP-PNP, although a substrate for the K⁺-dependent phosphatase reaction also catalyzed by this enzyme,p-nitrophenyl phosphate, did not. This lack of competition is consistent with formulations in which the phosphatase reaction is catalyzed at the low-affinity substrate sites.     

Evaluation of blood-brain barrier penetration and examination of binding to human serum albumin of 7-O-arylpiperazinylcoumarins as potential antipsychotic agents

The delivery of drugs to the brain is complicated by the multiple factors including low blood–brain barrier (BBB) passive permeability, active BBB efflux systems, and plasma protein binding. Thus, a detailed understanding of the transport of the new potent substances through the membranes is vitally important and their physico-chemical characteristics should be analyzed at first. This work presents an evaluation of drug likeness of eight 7-O-arylpiperazinylcoumarin derivatives with high affinity towards serotoninergic receptors 5-HT_1A and 5-HT_2A with particular analysis of the requirements for the CNS chemotherapeutics. The binding constants to human serum albumin (HSA) were determined at physiological pH using fluorescence spectroscopy, and then their mode of action was explained by analysis of theoretical HSA complexes. Dynamic simulation of systems allowed for reliable evaluation of the interaction strength. The analyzed coumarins were able to pass BBB, and they present good drug likeness properties. They showed high affinities to HSA (log K_Q = 5.3–6.0 which corresponds to −8.12 to −7.15 kcalmol⁻¹ of Gibbs free energy). The changes of the emission intensity upon binding to HSA were scrutinized showing the different mode of action for 4-phenylpiperazinylcoumarins. The values of computed Gibbs free energy and determined on the basis of experimentally obtained binding constants log K_Q coincide suggesting a good quality of the theoretical model. Overall the 8-acetyl-7-O-arylpiperazinyl-4-methylcoumarin derivatives represent valuable lead compounds to be further tested in various preclinical assays as a possible chemotherapeutics against CNS diseases. Studied coumarins can be metabolized by cytochrome P450 to aldehydes and hydroxy derivatives. The existence of other binding sites inside HSA than Sudlow’s site 1 was postulated. The longer aliphatic linker between coumarin and piperazine moieties favored binding to HSA in other than Sudlow site 1 pocket.     

Occupancy of two primary chloride-binding sites in Natronobacterium pharaonis halorhodopsin is a necessary condition for active anion transport

The existence of two primary chloride-binding sites was found on the basis of the study of halorhodopsin spectra at different chloride concentrations. SVD analysis of the spectra revealed two chloride-dependent components at low chloride concentration (0.1-10 mM). Global fitting of SVD components found K _D values of 0.47 mM and 5.2 mM with unitity Hill coefficients. The second K _D coincides with the apparent K _D of the photovoltage response of halorhodopsin.