Uncovering false positives on a virtual screening search for cruzain inhibitors

Some unexpected promiscuous inhibitors were observed in a virtual screening protocol applied to select cruzain inhibitors from the ZINC database. Physical-chemical and pharmacophore model filters were used to reduce the database size. The selected compounds were docked into the cruzain active site. Six hit compounds were tested as inhibitors. Although the compounds were designed to be nucleophilically attacked by the catalytic cysteine of cruzain, three of them showed typical promiscuous behavior, revealing that false positives are a prevalent concern in VS programs.     

Co-existence of alpha-glucosidase-inhibitory and liver X receptor-regulatory activities and their separation by structural development

Liver X receptors (LXR), which were originally reported as oxysterol-activated nuclear receptors, were recently found to recognize glucose as a physiological ligand. On this basis, we have already developed novel LXR antagonists based upon alpha-glucosidase inhibitors derived from thalidomide. Here, to clarify the relationship between alpha-glucosidase inhibition and LXR modulation, we investigate the alpha-glucosidase-inhibitory activity of typical LXR ligands and the LXR-modulating activity of typical alpha-glucosidase inhibitors. Although there were some exceptions, co-existence of LXR-regulatory and alpha-glucosidase-inhibitory activities seemed to be rather general among the examined compounds. The LXR ligands were found to be non-competitive alpha-glucosidase inhibitors, suggesting that it might be possible to separate the two activities. To test this idea, we focused on riccardin C, a naturally occurring LXR ligand, which we found here to be a potent alpha-glucosidase inhibitor as well. Structural development of riccardin C afforded novel LXR antagonists lacking alpha-glucosidase-inhibitory activity, 19c and 19f, and a LXRalpha-selective antagonist, 22.     

Evaluation of the antioxidant and antiradical activities of substances and biological objects using iron-initiated chemiluminescence]

Antioxidative and antiradical activity of the following typical inhibitors of free radical reactions were investigated in the model systems: ethanol, ionol, uric acid, superoxide dismutase, albumin. The antioxidative and antiradical activities of these inhibitors were shown to differ in various model systems.     

Topoisomerase II in multiple drug resistance

Topoisomerase II is a target of alkaloid, anthracycline and related antitumor agents. Two types of multiple drug resistance are associated with these enzymes. In classical (typical) multidrug resistance, inhibitors are actively effluxed from cells by P-glycoprotein. In atypical multidrug resistance, topoisomerase II is either reduced in cellular content or mutated to a form that does not interact with inhibitors. Because cytotoxicity of most antineoplastic topoisomerase II inhibitors is directly related to the number of active topoisomerase II molecules, a reduction in this number leads to resistance. In the topoisomerase II mechanism, through which the DNA linking number is altered, DNA double strands are cleaved, and the termini transiently bound covalently (5) or noncovalently (3) to the enzyme while a second double strand is passed through the break in the first. This transition state complex then decays to enzyme and DNA of altered linking number. Most cytotoxic topoisomerase II inhibitors stabilize these reaction intermediates as ternary complexes, which are converted to lethal lesions when cells attempt to utilize the damaged DNA as templates. Toxicity is related to topoisomerase II content as well as to drug concentration. Thus, multidrug resistance results from either 1) decreasing cellular content of the inhibitor by P-glycoprotein (typical) or 2) decreasing cellular content and/or activity of the target, topoisomerase II, as, for example, when its content or activity is modulated downward by decreased expression, deactivation, or by mutations to the TopII gene, producing an enzyme that reacts poorly with inhibitors (atypical). Mixed types,i.e., both typical and atypical, are known. Attempts to abrogate or prevent both typical and atypical multidrug resistance to topoisomerase II inhibitors have been described.Abbreviations atMDR atypical multidrug resistance - kDa kilodaltons - MDR multidrug resistance - Pgp P-glycoprotein - TOPO II topoisomerase II     

Extensive post-translational processing of potato tuber storage proteins and vacuolar targeting

Potato tuber storage proteins were obtained from vacuoles isolated from field-grown starch potato tubers cv. Kuras. Vacuole sap proteins fractionated by gel filtration were studied by mass spectrometric analyses of trypsin and chymotrypsin digestions. The tuber vacuole appears to be a typical protein storage vacuole absent of proteolytic and glycolytic enzymes. The major soluble storage proteins included 28 Kunitz protease inhibitors, nine protease inhibitors 1, eight protease inhibitors 2, two carboxypeptidase inhibitors, eight patatins and five lipoxygenases (lox), which all showed cultivar-specific sequence variations. These proteins, except for lox, have typical endoplasmic reticulum (ER) signal peptides and putative vacuolar sorting determinants of either the sequence or structure specific type or the C-terminal type, or both. Unexpectedly, sap protein variants imported via the ER showed multiple molecular forms because of extensive and unspecific proteolytic cleavage of exposed N- and C-terminal propeptides and surface loops, in spite of the abundance of protease inhibitors. Some propeptides are potential novel vacuolar targeting peptides. In the insoluble vacuole fraction two variants of phytepsin (aspartate protease) were identified. These are most probably the processing enzymes of potato tuber vacuolar proteins. Database Proteome data have been submitted to the PRIDE database under accession number 17707.     

Substrate Binding Sites of Leuconostoc Dextransucrase Evaluated by Inhibition Kinetics

Graphical analysis of inhibition kinetics for dextransucrase from Leuconostoc mesenteroides was done with typical inhibitors, competitive and noncompetitive. Based on the plots of Yonetani-Theorell and Semenza-Balthazar, mutual competition between the pairs of inhibitors of identical kinetic type was observed, while combination of competitive and noncompetitive inhibitors gave no significant mutual interactions. By the procedure of Nitta et al., binding sites for competitive and noncompetitive inhibitors were shown to be distant from each other. Moreover, two noncompetitive inhibitors competed with each other for a single binding site on the enzyme. Although biphasic reciprocal plots may suggest rather complicated binding of various inhibitors, the results obtained by the three graphical methods are fully explained when competitive and noncompetitive inhibitors for substrate sucrose bind to the so-called donor- and acceptor-sites of dextransucrase, respectively.     

Compounds with the dioxopyrimidine cycle inhibit cholinesterases from different groups of animals

We firstly synthesized derivatives of 6-methyluracil, alloxazine, and xanthine, containing omega-tetraalkylammonium (TAA) groups at the N(1) and N(3) atoms in a pyrimidine cycle and assayed their anticholinesterase activities. Compounds with triethylpentylammoniumalkyl groups behaved as typical reversible inhibitors of acetylcholinesterase (AChE) (pI(50) 3.20-6.22) and butyrylcholinesterase (BuChE) (pI(50) 3.05-5.71). Compounds, containing two ethyl residues and a substituted benzyl fragment in the tetraalkylammonium group at N(3) atoms or two similar TAA groups at N(1) and N(3) atoms, possessed very high anticholinesterase activity. Although these compounds displayed the activity of typical irreversible AChE inhibitors (a progressive AChE inactivation; k(i) 7.6x10(8) to 3.5x10(9)M(-1)min(-1)), they were reversible inhibitors of BuChE (pI(50) 3.9-6.9). The efficiency of AChE inhibition by some of these compounds was more than 10(4) times higher than the efficiency of BuChE inhibition. Several synthesized TAA derivates of 6-methyluracil reversibly inhibited electric eel and cobra venom AChEs and horse serum BuChE. However, depending on their structure, the tested compounds possessed the time-progressing inhibition of mammalian erythrocyte AChE, typically of irreversible inhibitors. As shown upon dialysis and gel-filtration, the formed mammalian AChE-inhibitor complex was stable. Thus, a new class of highly active, selective, and irreversible inhibitors of mammalian AChE was described. In contrast to classical phosphorylating or carbamoylating AChE inhibitors, these compounds are devoid of acylating functions. Probably, these inhibitors interact with certain amino acid residues at the entrance to the active-site gorge.     

Synergistic induction of erythroid differentiation of mouse erythroleukemia (MEL) cells by inhibitors of topoisomerases and protein tyrosine kinases.

In vitro erythroid differentiation of mouse erythroleukemia (MEL) cells was induced by combinations of topoisomerase and protein kinase inhibitors. Neither inhibitor alone exhibited inducing activity. Although inhibitors of topoisomerases I and II were equally effective in the synergistic induction of erythroid differentiation, only inhibitors of tyrosine kinases, not of serine/threonine kinases, exhibited synergistic activity. The erythroid differentiation induced by the combination of topoisomerase and protein tyrosine kinase inhibitors was distinguished from that induced by typical erythroid inducing agents such as DMSO or HMBA by (1) earlier hemoglobin accumulation in the cells and (2) insensitivity to specific inhibitors (dexamethasone and sodium orthovanadate) of MEL cell differentiation.     

Kinase selectivity profiling by inhibitor affinity chromatography

As new drugs rapidly advance into clinical trials, comprehensive identification of their intracellular targets becomes fundamental for the full understanding of the molecular basis of their efficacy and toxicity. This is particularly important when the targets belong to a large family and the inhibitors recognize a conserved site among different members of the class. A typical example is the kinase family, where efforts are aimed at the development of inhibitors of distinct kinases for therapeutic applications in oncology, inflammation and other disease areas. In this case, inhibitors targeting the ATP pocket may cross react with different kinases, as well as with other proteins that bind ATP. This review critically discusses the available approaches for kinase selectivity profiling. It also reviews some examples of inhibitor affinity chromatography applied to inhibitors of kinases and other protein families as a tool to identify and characterize their intracellular targets.     

Kinase selectivity profiling by inhibitor affinity chromatography

As new drugs rapidly advance into clinical trials, comprehensive identification of their intracellular targets becomes fundamental for the full understanding of the molecular basis of their efficacy and toxicity. This is particularly important when the targets belong to a large family and the inhibitors recognize a conserved site among different members of the class. A typical example is the kinase family, where efforts are aimed at the development of inhibitors of distinct kinases for therapeutic applications in oncology, inflammation and other disease areas. In this case, inhibitors targeting the ATP pocket may cross react with different kinases, as well as with other proteins that bind ATP. This review critically discusses the available approaches for kinase selectivity profiling. It also reviews some examples of inhibitor affinity chromatography applied to inhibitors of kinases and other protein families as a tool to identify and characterize their intracellular targets.     

A novel mechanism by which small molecule inhibitors induce the DFG flip in Aurora A

Most protein kinases share a DFG (Asp-Phe-Gly) motif in the ATP site that can assume two distinct conformations, the active DFG-in and the inactive DFG-out states. Small molecule inhibitors able to induce the DFG-out state have received considerable attention in kinase drug discovery. Using a typical DFG-in inhibitor scaffold of Aurora A, a kinase involved in the regulation of cell division, we found that halogen and nitrile substituents directed at the N-terminally flanking residue Ala273 induced global conformational changes in the enzyme, leading to DFG-out inhibitors that are among the most potent Aurora A inhibitors reported to date. The data suggest an unprecedented mechanism of action, in which induced-dipole forces along the Ala273 side chain alter the charge distribution of the DFG backbone, allowing the DFG to unwind. As the ADFG sequence and three-dimensional structure is highly conserved, DFG-out inhibitors of other kinases may be designed by specifically targeting the flanking alanine residue with electric dipoles.     

Properties of purified gut trypsin from Helicoverpa zea, adapted to proteinase inhibitors.

Pest insects such as Helicoverpa spp. frequently feed on plants expressing protease inhibitors. Apparently, their digestive system can adapt to the presence of protease inhibitors. To study this, a trypsin enzyme was purified from the gut of insects that were raised on an inhibitor-containing diet. The amino-acid sequence of this enzyme was analysed by tandem MS, which allowed assignment of 66% of the mature protein amino acid sequence. This trypsin, called HzTrypsin-S, corresponded to a known cDNA sequence from Helicoverpa. The amino acid sequence is closely related (76% identical) to that of a trypsin, HzTrypsin-C, which was purified and identified in a similar way from insects raised on a diet without additional inhibitor. The digestive properties of HzTrypsin-S and HzTrypsin-C were compared. Both trypsins appeared to be equally efficient in degrading protein. Four typical plant inhibitors were tested in enzymatic measurements. HzTrypsin-S could not be inhibited by > 1000-fold molar excess of any of these. The same inhibitors inhibited HzTrypsin-C with apparent equilibrium dissociation constants ranging from 1 nm to 30 nm. Thus, HzTrypsin-S seems to allow the insect to overcome different defensive proteinase inhibitors in plants.     

Double-headed protease inhibitors from black-eyed peas. II. Structural studies by optical absorption and circular dichroism.

Two new double-headed protease inhibitors from black-eyed peas have amino acid compositions typical of the low molecular weight protease inhibitors from legume seeds. Black-eyed pea chymotrypsin and trypsin inhibitor (BEPCI) contains no tryptophan, 1 tyrosine, and 14 half-cystines out of 83 amino acid residues per monomer. Black-eyed pea trypsin inhibitor (BEPTI) contains no tryptophan, 1 tyrosine, and 14 half-cystines out of 75 residues per monomer. The molar extinctions at 280 nm are 2770 for BEPCI and 3440 for BEPTI. The single tyrosyl residue is very inaccessible to solvent in native BEPCI and BEPTI at neutral pH and titrates anomalously with an apparent pK = 12. Ionization of tyrosine is complete in 13 hours above pH 12. No heterogeneity of the local environment of the tyrosyl residues in different subunits can be detected spectrophotometrically. The large number of cystine residues leads to an intense and complex near-ultraviolet CD spectrum with cystine contributions in the regions of 248 and 280 nm and tyrosine contributions at 233 and 280 nm. An intact disulfide structure is required for appearance of the tyrosyl CD bands. The inhibitors are unusually resistant to denaturation when compared with similar low molecular weight proteins of high disulfide content. All observations are consistent with a far more rigid structure for BEPCI and BEPTI than for a typical protein.     

应用生物技术降解木质纤维素水解液中呋喃醛

木质纤维素是地球上储量最为丰富的可再生有机碳资源,但由于其结构的复杂性,必须经过一系列预处理过程才能被微生物高效利用,这就不可避免地带来了呋喃醛等典型抑制物,严重阻碍了微生物的生长和后续发酵过程。认知微生物的呋喃醛代谢途径,并基于此开发耐受性和转化能力强的微生物菌株是生物炼制领域的重要研究内容。文中综述了呋喃醛抑制物的来源、呋喃醛对微生物的抑制机理以及微生物降解呋喃醛的代谢途径,并重点讨论了基于生物法降解呋喃醛抑制物的研究进展,涉及的主要技术手段包括传统的适应性进化工程和代谢工程,以及近年来新兴的微生物共培养系统和功能化材料辅助微生物脱除呋喃醛等。     

Steered Molecular Dynamics Simulations Reveal the Likelier Dissociation Pathway of Imatinib from Its Targeting Kinases c-Kit and Abl

Development of small molecular kinase inhibitors has recently been the central focus in drug discovery. And type II kinase inhibitors that target inactive conformation of kinases have attracted particular attention since their potency and selectivity are thought to be easier to achieve compared with their counterpart type I inhibitors that target active conformation of kinases. Although mechanisms underlying the interactions between type II inhibitors and their targeting kinases have been widely studied, there are still some challenging problems, for example, how type II inhibitors associate with or dissociate from their targeting kinases. In this investigation, steered molecular dynamics simulations have been carried out to explore the possible dissociation pathways of typical type II inhibitor imatinib from its targeting protein kinases c-Kit and Abl. The simulation results indicate that the most favorable pathway for imatinib dissociation corresponds to the ATP-channel rather than the relatively wider allosteric-pocket-channel, which is mainly due to the different van der Waals interaction that the ligand suffers during dissociation. Nevertheless, the direct reason comes from the fact that the residues composing the ATP-channel are more flexible than that forming the allosteric-pocket-channel. The present investigation suggests that a bulky hydrophobic head is unfavorable, but a large polar tail is allowed for a potent type II inhibitor. The information obtained here can be used to direct the discovery of type II kinase inhibitors.     

α-amylase inhibitors in Triticum aestivum: Purification and physical-chemical properties

Two α-amylase inhibitors in aqueous extracts of wheat flour have been resolved by DEAE-Sephadex chromatography. α-Amylase inhibitor I, the major inhibitor, was homogeneous by disc gel electrophoresis. It had a MW of 20 000 daltons and an isoelectric point of 6·7. α-Amylase inhibitor II had two minor contaminants when analysed by electrophoresis. These inhibitors were classified as typical wheat albumin proteins. A third α-amylase inhibitor was discovered when it was observed that an albumin protein which is found only in Triticum aestivum varieties of wheat could also inhibit pancreatic α-amylase. All three of these inhibitors could be distinguished by their characteristic electrophoretic mobilities.     

Metal mediated inhibition of methionine aminopeptidase by quinolinyl sulfonamides

Quinolinyl sulfonamides, such as N-(quinolin-8-yl)methanesulfonamide (10) and N-(5-chloroquinolin-8-yl)methanesulfonamide (11), were identified as potent methionine aminopeptidase (MetAP) inhibitors by high throughput screening of a diverse chemical library of small organic compounds. They showed different inhibitory potencies on Co(II)-, Ni(II)-, Fe(II)-, Mn(II)-, and Zn(II)-forms of Escherichia coli MetAP, and their inhibition is dependent on metal concentration. X-ray structures of E. coli MetAP complexed with 10 revealed that the inhibitor forms a metal complex with the residue H79 at the enzyme active site; the complex is further stabilized by an extended H-bond and metal interaction network. Analysis of the inhibition of MetAP by these inhibitors indicates that this is a typical mechanism of inhibition for many non-peptidic MetAP inhibitors and emphasizes the importance of defining in vitro conditions for identifying and evaluating MetAP inhibitors that will be capable of giving information relevant to the in vivo situation.     

Active transport of ferric schizokinen in Anabaena sp

The cyanobacterium Anabaena sp. strain ATCC 27898 was found to utilize the siderophore schizokinen to accumulate iron from the environment. This organism had previously been shown to produce schizokinen under low-iron conditions, and we observed that the iron-transport capability is also increased in response to iron limitation. Uptake activity was specific for ferric schizokinen displayed kinetics typical of a protein-mediated process with an apparent Km of 0.04 microM and saturation at high concentrations of substrate. Light-driven transport was blocked by uncouplers and by ATPase inhibitors. Transport in dark-adapted cells was additionally blocked by inhibitors of respiration. We conclude that ATP serves as an energy source for the cellular uptake of ferric schizokinen.     

Crystal structure of the tyrosine kinase domain of colony-stimulating factor-1 receptor (cFMS) in complex with two inhibitors

The cFMS proto-oncogene encodes for the colony-stimulating factor-1 receptor, a receptor-tyrosine kinase responsible for the differentiation and maturation of certain macrophages. Upon binding its ligand colony-stimulating factor-1 cFMS autophosphorylates, dimerizes, and induces phosphorylation of downstream targets. We report the novel crystal structure of unphosphorylated cFMS in complex with two members of different classes of drug-like protein kinase inhibitors. cFMS exhibits a typical bi-lobal kinase fold, and its activation loop and DFG motif are found to be in the canonical inactive conformation. Both ATP competitive inhibitors are bound in the active site and demonstrate a binding mode similar to that of STI-571 bound to cABL. The DFG motif is prevented from switching into the catalytically competent conformation through interactions with the inhibitors. Activation of cFMS is also inhibited by the juxtamembrane domain, which interacts with residues of the active site and prevents formation of the activated kinase. Together the structures of cFMS provide further insight into the autoinhibition of receptor-tyrosine kinases via their respective juxtamembrane domains; additionally the binding mode of two novel classes of kinase inhibitors will guide the design of novel molecules targeting macrophage-related diseases.     

The p-nitrophenyl phosphatase activity of ubiquitin from bovine erythrocytes

Ubiquitin, a unique protein with esterase and carbonic anhydrase activity, has been found to have also a p-nitrophenyl phosphatase activity. This phosphomonoesterase activity of ubiquitin has an acidic pH optimum; its true substrate appears to be the phosphomonoanion, with a Km of 1.8 X 10(-3) M. It is competitively inhibited by the typical acid phosphatase inhibitors, arsenate (Ki = 1.3 X 10(-3) M), molybdate (Ki = 1.2 X 10(-6) M), and phosphate (Ki = 1.4 X 10(-3) M). These inhibitors have no effect on the CO2 hydration and p-nitrophenyl acetate esterase activities of the ubiquitin. Acetazolamide slightly inhibited the p-nitrophenyl phosphatase activity.