Gamone Production in Large-Scale Cultures of Euplotes octocarinatus1

We report a method that allows us to grow and maintain the freshwater ciliate Euplotes octocarinatus in large quantities. Frequent exchange of culture fluid proved more effective than aeration in obtaining high cell densities (4200 cells/ml) and reasonable doubling times in large-scale cultures. For harvesting gamone 1, the cell density was raised to 10,000 cells/ml. Under these conditions, the cells continued to produce and secrete gamone; they were slightly starved, but they no longer divided. Cell-free fluid with a steady and relatively high yield of gamone was obtained from two such cultures over a period of five months. We isolated gamone 1 also from cell homogenates and compared it with secreted gamone 1, but found no differences in the gamones from these two sources.     

Unidirectional co-stimulation by a non-mating strain of Tetrahymena thermophila

We report that a fatty acid auxotroph of Tetrahymena thermophila (RH179E1) fails to mate, yet retains the ability to co-stimulate normal cells unidirectionally. Thus, co-stimulation can be analyzed experimentally in the absence of pair formation. We show that the co-stimulation of normal cells of one mating type is sufficient to shorten the waiting period for pair formation of those cells with initiated cells. This is the first evidence that co-stimulation causes a hyperinduction of mating reactivity in T. thermophila, generating in turn a positive feedback mechanism for (presumably) gamone production. Co-stimulation by the variant strain is at a maximum after 3-4 h of exposure when the variant and wild-type cells are at a ratio of 1:1. When mixed with wild-type cells, RH179E1 induces the formation of progeny (at low frequency) which inherit exclusively genetic material of the wild-type cells.     

Inclusion of ionization states of ligands in affinity calculations

When estimating binding affinities of a ligand, which can exists in multiple forms, for a target molecule, one must consider all possible competing equilibria. Here, a method is presented that estimates the contribution of the protonation equilibria of a ligand in solution to the measured or calculated binding affinity. The method yields a correction to binding constants that are based on the total concentration of inhibitor (the sum of all ionized forms of the inhibitor in solution) to account for the complexed form of the inhibitor only. The method is applied to the calculation of the difference in binding affinity of two inhibitors, 2‐phosphoglycolate (PGA) and its phoshonate analog 3‐phosphonopropionate (3PP), for the glycolytic enzyme triosephosphate isomerase. Both inhibitors have three titrating sites and exist in solution as a mixture of different forms. In this case the form that actually binds to the enzyme is present at relative low concentrations. The contributions of the alternative forms to the difference in binding energies is estimated by means of molecular dynamics simulations and corrections. The inhibitors undergo a pK_a shift upon binding that is estimated by ab initio calculations. An interesting finding is that the affinity difference of the two inhibitors is not due to different interactions in the active site of the enzyme, but rather due to the difference in the solvation properties of the inhibitors. Protein 2009. © 2008 Wiley‐Liss, Inc.     

Alternative gene expression in type I and type II cells may enable further nuclear changes during conjugation of Blepharisma japonicum

In contrast to most ciliates, meiosis and successive nuclear changes during conjugation occur only in heterotypic pairs in Blepharisma. It has been suggested that homotypic pairs are ready for conjugation, but lack a trigger to initiate the nuclear changes, and the conjugation process is arrested before the onset of meiosis. To explore the possible nature of the trigger, we previously identified the genes BjCdk1 (homologous to cdk1/cdc2), Bj4HPPD (4-hydroxy-phenylpyruvate dioxygenase) and BjCks (cyclin dependent kinase regulatory subunit) whose expression is up-regulated in gamone1-treated type II cells. In this study, we investigated the molecular structures of these three genes, and compared their expression patterns in homotypic and heterotypic pairs, finding remarkable differences. BjCdk1, Bj4HPPD and BjCks were expressed specifically in gamone1-treated type II cells, but not in gamone2-treated type I cells. In heterotypic pairs, the expression of these genes stayed at the same level or gradually decreased throughout the entire process of conjugation, but it rapidly decreased and ceased after 10hours in homotypic pairs. These results indicate that some genes are expressed in a mating-type specific manner. Alternative gene expression in mating type I and type II cells and merging of individual factors in a heterotypic pair may induce nuclear changes including meiosis.     

Behavioural changes induced by the conjugation-inducing pheromones,gamone 1 and 2, in the ciliate Blepharisma japonicum

Preconjugant interactions between complementary mating-type cells in ciliates occur before sexual reproduction. The interactions include retardation of swimming behaviour, courtship dancing, chemoattraction, nuclear activation, cell division, or cell agglutination, depending on ciliate species. In Blepharisma japonicum, chemoattraction of mating-type I by mating-type II has been reported previously. It has been shown that chemoattraction here is caused by a conjugation-inducing substance called gamone 2 secreted by mating-type II cells. In this study, we show that mating-type II cells accumulate near the site where gamone 1 secreted by mating-type I cells is present at a high concentration. We also show that the behaviour of individual cells changes when exposed to the complementary mating-type gamone; cells begin to rotate and swim slowly, thus shortening their minimum path length (final displacement of a cell from its origin). These results suggest that gamones 1 and 2 induce behavioural changes in type II and I cells, respectively, and that gamone-stimulated cells may accumulate at the site with the highest activity of the complementary gamone, after repetition of swimming changes in the gradient of gamone concentration. This reciprocal induction of the changes in behaviour may increase the probability of sexual encounters for conjugation.     

Isolation and partial characterization of gamone 1 of Euplotes octocarinatus

A polypeptide, termed gamone 1, was isolated and purified to homogeneity from culture filtrates of mating type VII of the freshwater ciliate Euplotes octocarinatus. The gamone induces intraclonal conjugation in cells of certain other mating types. The isolation and purification of the gamone was carried out by a combination of two chromatographic steps. The purified gamone was found to be still effective in a concentration of approx. 10⁻¹⁵M.     

Design and synthesis of highly potent HIV-1 protease inhibitors with novel isosorbide-derived P2 ligands

The design, synthesis, and biological evaluation of a series of six HIV-1 protease inhibitors incorporating isosorbide moiety as novel P2 ligands are described. All the compounds are very potent HIV-1 protease inhibitors with IC₅₀ values in the nanomolar or picomolar ranges (0.05–0.43 nM). Molecular docking studies revealed the formation of an extensive hydrogen-bonding network between the inhibitor and the active site. Particularly, the isosorbide-derived P2 ligand is involved in strong hydrogen bonding interactions with the backbone atoms.     

An experimental method for the determination of enzyme-competitive inhibitor dissociation constants from displacement curves: application to human renin using fluorescence energy transfer to a synthetic dansylated inhibitor peptide

We developed a facile procedure for the determination of enzyme-competitive inhibitor dissociation constants over a wide range of potencies at any ratios of enzyme, labeled ligand, and inhibitor. The assay uses displacement curves and a fluorescent-labeled ligand to allow experimental determination of dissociation constants (Kd's) of inhibitors of human renin, a highly specific enzyme, for which numerous high affinity (up to 100 pM) inhibitors have been synthesized. The procedure involves binding a dansylated competitive inhibitor, U80215, followed by its displacement by an unlabeled inhibitor of renin. Binding of U80215 is monitored by fluorescent energy transfer from the renin tryptophans to the dansyl moiety; displacement of U80215 by an unlabeled inhibitor is monitored by a reversal of this process. The procedures may be used to determine the potencies of unlabeled inhibitors up to 100 pM affinities and to determine kinetic binding constants. The concepts described should also be useful in other protein/ligand systems.     

Scoring ligand similarity in structure‐based virtual screening

Scoring to identify high‐affinity compounds remains a challenge in virtual screening. On one hand, protein–ligand scoring focuses on weighting favorable and unfavorable interactions between the two molecules. Ligand‐based scoring, on the other hand, focuses on how well the shape and chemistry of each ligand candidate overlay on a three‐dimensional reference ligand. Our hypothesis is that a hybrid approach, using ligand‐based scoring to rank dockings selected by protein–ligand scoring, can ensure that high‐ranking molecules mimic the shape and chemistry of a known ligand while also complementing the binding site. Results from applying this approach to screen nearly 70 000 National Cancer Institute (NCI) compounds for thrombin inhibitors tend to support the hypothesis. EON ligand‐based ranking of docked molecules yielded the majority (4/5) of newly discovered, low to mid‐micromolar inhibitors from a panel of 27 assayed compounds, whereas ranking docked compounds by protein–ligand scoring alone resulted in one new inhibitor. Since the results depend on the choice of scoring function, an analysis of properties was performed on the top‐scoring docked compounds according to five different protein–ligand scoring functions, plus EON scoring using three different reference compounds. The results indicate that the choice of scoring function, even among scoring functions measuring the same types of interactions, can have an unexpectedly large effect on which compounds are chosen from screening. Furthermore, there was almost no overlap between the top‐scoring compounds from protein–ligand versus ligand‐based scoring, indicating the two approaches provide complementary information. Matchprint analysis, a new addition to the SLIDE (Screening Ligands by Induced‐fit Docking, Efficiently) screening toolset, facilitated comparison of docked molecules' interactions with those of known inhibitors. The majority of interactions conserved among top‐scoring compounds for a given scoring function, and from the different scoring functions, proved to be conserved interactions in known inhibitors. This was particularly true in the S1 pocket, which was occupied by all the docked compounds. Copyright © 2009 John Wiley & Sons, Ltd.     

Novel Transthyretin Amyloid Fibril Formation Inhibitors: Synthesis,Biological Evaluation,and X-Ray Structural Analysis

Transthyretin (TTR) is one of thirty non-homologous proteins whose misfolding, dissociation, aggregation, and deposition is linked to human amyloid diseases. Previous studies have identified that TTR amyloidogenesis can be inhibited through stabilization of the native tetramer state by small molecule binding to the thyroid hormone sites of TTR. We have evaluated a new series of β-aminoxypropionic acids (compounds 5–21), with a single aromatic moiety (aryl or fluorenyl) linked through a flexible oxime tether to a carboxylic acid. These compounds are structurally distinct from the native ligand thyroxine and typical halogenated biaryl NSAID-like inhibitors to avoid off-target hormonal or anti-inflammatory activity. Based on an in vitro fibril formation assay, five of these compounds showed significant inhibition of TTR amyloidogenesis, with two fluorenyl compounds displaying inhibitor efficacy comparable to the well-known TTR inhibitor diflunisal. Fluorenyl 15 is the most potent compound in this series and importantly does not show off-target anti-inflammatory activity. Crystal structures of the TTR∶inhibitor complexes, in agreement with molecular docking studies, revealed that the aromatic moiety, linked to the sp²-hybridized oxime carbon, specifically directed the ligand in either a forward or reverse binding mode. Compared to the aryl family members, the bulkier fluorenyl analogs achieved more extensive interactions with the binding pockets of TTR and demonstrated better inhibitory activity in the fibril formation assay. Preliminary optimization efforts are described that focused on replacement of the C-terminal acid in both the aryl and fluorenyl series (compounds 22–32). The compounds presented here constitute a new class of TTR inhibitors that may hold promise in treating amyloid diseases associated with TTR misfolding.     

Synthesis of polyvalent inhibitors of controlled molecular weight: structure-activity relationship for inhibitors of anthrax toxin

We describe a novel method to synthesize activated polymers of controlled molecular weight and apply this method to investigate the relationship between the structure and activity of polyvalent inhibitors of anthrax toxin. In particular, we observe an initial sharp increase in potency with increasing ligand density, followed by a plateau where potency is independent of ligand density. Our simple strategy for designing polyvalent inhibitors of controlled molecular weight and ligand density will be broadly applicable for designing inhibitors for a variety of pathogens and toxins, and for elucidating structure-activity relationships in these systems. Our results also demonstrate a role for kinetics in influencing inhibitory potency in polyvalent systems. Finally, our work presents a synthetic route to polyvalent inhibitors that are more structurally defined and effective in vivo. This control over inhibitor composition will be generally useful for the optimization of inhibitor potency and pharmacokinetics, and for the eventual application of these molecules in vivo.     

Active-site directed inactivation of rat ovarian 20 alpha-hydroxysteroid dehydrogenase.

Rat ovarian 20 alpha-hydroxysteroid dehydrogenase plays a pivotal role in leuteolysis and parturition by catalysing the reduction of progesterone to give the progestationally inactive steroid 20 alpha-hydroxyprogesterone. Putative mechanism based inhibitors of this enzyme were synthesized as potential progestational maintaining agents, including the epimeric allylic alcohol pair 3 beta-hydroxy-alpha-vinyl-5 alpha-androstane-17 beta-methanol and the related vinyl ketone 1-(3 beta-hydroxy-5 alpha-androstan-17 beta-yl)-2-propen-1-one. The vinyl ketone inactivates rat ovarian 20 alpha-hydroxysteroid dehydrogenase, semi-purified by poly(L-lysine)-agarose column chromatography, in a rapid time-dependent manner. Analysis of the pseudo-first-order inactivation plots gave a Ki of 2.0 microM for the inhibitor and a t1/2 for the enzyme of 20 s at saturation. These data indicate that the vinyl ketone is a potent and efficient inactivator of the ovarian dehydrogenase. Neither dialysis in the presence or absence of a competing nucleophile nor gel filtration reserves the inactivation, suggesting that a stable covalent bond is formed between the enzyme and steroid ligand. Both substrates (20 alpha-hydroxyprogesterone and NADP+) protect the enzyme from inactivation; moreover, initial velocity measurements in the presence of saturating concentrations of both substrates indicate that the vinyl ketone can behave as a competitive inhibitor, yielding a Ki value identical with that obtained in the inactivation experiments. Our results imply that the vinyl ketone is an active-site directed alkylating agent. By contrast the allylic alcohol pair 3 beta-hydroxy-alpha-vinyl-5 alpha-androstane-17 beta-methanol are neither substrates nor inhibitors of the ovarian enzyme and appear to be excluded from the catalytic site. The rapid inactivation observed with the vinyl ketone suggests that this compound may be useful as a progestational maintaining agent.     

Molecular simulations as a tool for selection of kinetic hydrate inhibitors

Natural gas hydrates are ice-like structures in which water molecules form a cage around gas molecules. They have been a problem in the petroleum industry. The heavy cost of alcohol and glycol injections needed to suppress the formation of hydrates has spurred an interest in so-called “kinetic inhibitors”, able to slow down the hydrate formation rather than prevent it. An earlier work (Kvamme, B. et al. 1997, Mol. Phys., 90, p. 979) proposed a simulation-based scheme to assess the comparative performance of prospective inhibitors and select the best candidates for experimental testing. In this work, we employed molecular dynamics simulations to test several kinetic inhibitors in a multiphase water–hydrate system with rigid hydrate interface. In addition, a long-scale run was implemented for a system where the hydrate was free to melt and reform. Our conclusion that PVCap inhibitor will outperform PVP as a kinetic hydrate inhibitor is supported by experimental data. We demonstrate that numerical experiments can be a valuable tool for selecting kinetic inhibitors as well as provide insight into mechanisms of kinetic inhibition and hydrate melting and reformation.     

Equilibrium competition binding assay: inhibition mechanism from a single dose response

Inhibition of a receptor by a small-molecule compound in many cases is achieved via a competitive, uncompetitive or non-competitive mechanism. The receptor-inhibitor interaction is often probed through the displacement of a ligand in an equilibrium competition binding experiment. The previous solutions to receptor inhibition mechanisms were borrowed from steady-state enzyme inhibition mechanisms. The inhibition mechanism is determined by a visual inspection or a global fit of ligand dose response curves at a series of inhibitor concentrations. However these solutions only apply to situations when both the ligand and the inhibitor are not significantly depleted by the receptor. In most published equilibrium receptor binding studies, only the relative potency of the inhibitor is calculated. Ranking inhibitors tested under differing experimental conditions is often not possible. In the current paper, we offer exact mathematical solutions to uncompetitive and non-competitive inhibition, and demonstrate that in most cases both the inhibition mechanism and absolute potency of an inhibitor can be simultaneously determined from a single dose response of the inhibitor at a fixed concentration of the ligand. Therefore, an equilibrium competition assay provides a quick and facile method to determine the inhibition mechanism of a large number of inhibitors. The theory herein described is applicable to equilibrium competition binding experiments such as radioligand assays and fluorescence polarization assays.     

Maize Response to Salicylic Acid and Fusarium moniliforme

Effects of salicylic acid and Fusarium moniliformeon trypsin inhibitor activity, lectin activity, lectin carbohydrate specificity, and salicylic acid content in maize seedlings were studied. Changes in trypsin inhibitor activity, lectin activity, and the content of endogenous salicylic acid after administration of exogenous salicylic acid or a pathogen were shown to depend on the resistance of maize strains to Fusarium. The data suggest that salicylic acid is involved in the induction of trypsin and lectin inhibitors that are important in the formation of defenses against abiotic and biotic factors in maize sprouts.     

INHIBITION OF ASTAXANTHIN SYNTHESIS UNDER HIGH IRRADIANCE DOES NOT ABOLISH TRIACYLGLYCEROL ACCUMULATION IN THE GREEN ALGA HAEMATOCOCCUS PLUVIALIS (CHLOROPHYCEAE)1

Under stress conditions, Haematococcus pluvialis Flotow accumulates fatty acid–esterified astaxanthin, in extraplastidial lipid globules. The enhanced accumulation of fatty acids, mainly in triacylglycerols (TAG), among which oleic acid predominates, is linearly correlated with that of astaxanthin. We used inhibitors of either carotenoid or lipid biosynthesis to assess the interrelationship between carotenogenesis and TAG accumulation under high light irradiance as the stress factor. The two carotenogenesis inhibitors used—norflurazon, an inhibitor of phytoene desaturase, and diphenylamine (DPA), an inhibitor of β‐carotene C‐4 oxygenase—suppressed the accumulation of astaxanthin in a concentration‐dependent manner. Concurrently, the accumulation of neutral lipids was significantly less affected. The lipid biosynthesis inhibitor sethoxydim, which inhibits acetyl‐CoA carboxylase, significantly decreased de novo fatty acid synthesis and, in concert, drastically inhibited astaxanthin formation. In the presence of various concentrations of the three inhibitors, the inhibition of astaxanthin was not accompanied by a proportional decrease in oleic acid, which was used as a marker for TAG fatty acids. When astaxanthin synthesis was completely inhibited, the volumetric content of oleic acid was about 60% of the control value when the two carotenogenesis inhibitors (0.05 μM norflurazon or 20 μM DPA) were used and 27% of the control when the lipid‐synthesis inhibitor (50 μM) was used. We suggest therefore that TAG accumulation under high irradiance is not tightly coupled with astaxanthin accumulation, although the correlation between these two processes was demonstrated earlier. Furthermore, we propose that the accumulation of a certain amount of TAG is a prerequisite for the initiation of fatty acid–esterified astaxanthin accumulation in lipid globules.     

Examining the influence of specificity ligands and ATP-competitive ligands on the overall effectiveness of bivalent kinase inhibitors

Background

Identifying selective kinase inhibitors remains a major challenge. The design of bivalent inhibitors provides a rational strategy for accessing potent and selective inhibitors. While bivalent kinase inhibitors have been successfully designed, no comprehensive assessment of affinity and selectivity for a series of bivalent inhibitors has been performed. Here, we present an evaluation of the structure activity relationship for bivalent kinase inhibitors targeting ABL1.

Methods

Various SNAPtag constructs bearing different specificity ligands were expressed in vitro. Bivalent inhibitor formation was accomplished by synthesizing individual ATP-competitive kinase inhibitors containing a SNAPtag targeting moiety, enabling the spontaneous self-assembly of the bivalent inhibitor. Assembled bivalent inhibitors were incubated with K562 lysates, and then subjected to affinity enrichment using various ATP-competitive inhibitors immobilized to sepharose beads. Resulting eluents were analyzed using Tandem Mass Tag (TMT) labeling and two-dimensional liquid chromatography-tandem mass spectrometry (2D–LC-MS/MS). Relative binding affinity of the bivalent inhibitor was determined by calculating the concentration at which 50% of a given kinase remained bound to the affinity matrix.

Results

The profiling of three parental ATP-competitive inhibitors and nine SNAPtag conjugates led to the identification of 349 kinase proteins. In all cases, the bivalent inhibitors exhibited enhanced binding affinity and selectivity for ABL1 when compared to the parental compound conjugated to SNAPtag alone. While the rank order of binding affinity could be predicted by considering the binding affinities of the individual specificity ligands, the resulting affinity of the assembled bivalent inhibitor was not predictable. The results from this study suggest that as the potency of the ATP-competitive ligand increases, the contribution of the specificity ligand towards the overall binding affinity of the bivalent inhibitor decreases. However, the affinity of the specificity components in its interaction with the target is essential for achieving selectivity.

Conclusion

Through comprehensive chemical proteomic profiling, this work provides the first insight into the influence of ATP-competitive and specificity ligands binding to their intended target on a proteome-wide scale. The resulting data suggest a subtle interplay between the ATP-competitive and specificity ligands that cannot be accounted for by considering the specificity or affinity of the individual components alone.

     

Kinetics of ternary complex formation between dihydrofolate reductase, coenzyme, and inhibitors

The kinetics of ligand binding to dihydrofolate reductase from Lactobacillus casei (MTX/R) to form the ternary enzyme-inhibitor-coenzyme complex have been investigated by the stopped-flow fluorescence technique. The fluorescence changes observed when coenzymes or inhibitors bind to the binary complex of the enzyme with the complementary ligand occur in a single fast phase. Under pseudo-first-order conditions the reaction traces could be fitted with precision to a single-exponential decay, and apparent bimolecular rate constants in the range 2 x 10(6) to 3 x 10(7) M-1s-1 have been measured assuming a bimolecular-unimolecular model. The kinetic constants obtained suggest that prior binding of an inhibitor to the enzyme may, to a minor extent, interfere with coenzyme binding but the rates of inhibitor binding seem to be unaffected by the presence of a bound coenzyme. Dissociation rate constants appear to be less than 1 s-1 which suggests that both coenzymes and inhibitors are tightly bound in the ternary complex. An investigation of the effects of pH on the kinetics of ternary complex formation indicated the involvement of ionizable groups in ligand binding, but this shows some ligand dependence. The rates of ligand bindings to form the ternary complex are fairly high, but it is unlikely that these associations are diffusion controlled because their measured activation energies of 7.8-14.5 kcal mol-1 are higher than expected from reactions whose rates are limited by diffusion in aqeous solution.     

Studies on the amoebo-flagellate transformation inPhysarum polycephalum

Flagellar formation in the true slime mold,Physarum polycephalum, involves a sequence of events during which amoebae are changed into flagellate cells. In the present study a series of inhibitors thought to inhibit RNA and protein synthesis and microtubule assembly were added in an attempt to characterize the metabolic processes associated with this amoebo-flagellate transformation. Proflavin (inhibitor of cellular RNA synthesis), puromycin, cycloheximide and streptomycin (inhibitors of protein synthesis), blocked the transformation; however, actinomycin D (inhibitor of DNA-dependent RNA synthesis) did not block this transformation. On the other hand, 2-mercaptoethanol and dithiothreitol did block flagella formation, but even high concentrations of colchicine failed to have such an effect. Flagellate formation was more strongly inhibited by inhibitors of oxidative phosphorylation than by other respiratory inhibitors; this suggests that oxidative phosphorylation takes part in the energy metabolism of this transformation.