Network


Latest external collaboration on country level. Dive into details by clicking on the dots.

Hotspot


Dive into the research topics where Arie Ordentlich is active.

Publication


Featured researches published by Arie Ordentlich.


The EMBO Journal | 1992

Substrate inhibition of acetylcholinesterase: residues affecting signal transduction from the surface to the catalytic center.

Avigdor Shafferman; B Velan; Arie Ordentlich; C. Kronman; H Grosfeld; M Leitner; Y Flashner; S Cohen; Dov Barak; Naomi Ariel

Amino acids located within and around the ‘active site gorge’ of human acetylcholinesterase (AChE) were substituted. Replacement of W86 yielded inactive enzyme molecules, consistent with its proposed involvement in binding of the choline moiety in the active center. A decrease in affinity to propidium and a concomitant loss of substrate inhibition was observed in D74G, D74N, D74K and W286A mutants, supporting the idea that the site for substrate inhibition and the peripheral anionic site overlap. Mutations of amino acids neighboring the active center (E202, Y337 and F338) resulted in a decrease in the catalytic and the apparent bimolecular rate constants. A decrease in affinity to edrophonium was observed in D74, E202, Y337 and to a lesser extent in F338 and Y341 mutants. E202, Y337 and Y341 mutants were not inhibited efficiently by high substrate concentrations. We propose that binding of acetylcholine, on the surface of AChE, may trigger sequence of conformational changes extending from the peripheral anionic site through W286 to D74, at the entrance of the ‘gorge’, and down to the catalytic center (through Y341 to F338 and Y337). These changes, especially in Y337, could block the entrance/exit of the catalytic center and reduce the catalytic efficiency of AChE.


Journal of Biological Chemistry | 1998

Functional Characteristics of the Oxyanion Hole in Human Acetylcholinesterase

Arie Ordentlich; Dov Barak; Chanoch Kronman; Naomi Ariel; Yoffi Segall; Baruch Velan; Avigdor Shafferman

The contribution of the oxyanion hole to the functional architecture and to the hydrolytic efficiency of human acetylcholinesterase (HuAChE) was investigated through single replacements of its elements, residues Gly-121, Gly-122 and the adjacent residue Gly-120, by alanine. All three substitutions resulted in about 100-fold decrease of the bimolecular rate constants for hydrolysis of acetylthiocholine; however, whereas replacements of Gly-120 and Gly-121 affected only the turnover number, mutation of residue Gly-122 had an effect also on the Michaelis constant. The differential behavior of the G121A and G122A enzymes was manifested also toward the transition state analogm-(N,N,N-trimethylammonio)trifluoroacetophenone (TMTFA), organophosphorous inhibitors, carbamates, and toward selected noncovalent active center ligands. Reactivity of both mutants toward TMTFA was 2000–11,000-fold lower than that of the wild type HuAChE; however, the G121A enzyme exhibited a rapid inhibition pattern, as opposed to the slow binding kinetics shown by the G122A enzyme. For both phosphates (diethyl phosphorofluoridate, diisopropyl phosphorofluoridate, and paraoxon) and phosphonates (sarin and soman), the decrease in inhibitory activity toward the G121A enzyme was very substantial (2000–6700-fold), irrespective of size of the alkoxy substituents on the phosphorus atom. On the other hand, for the G122A HuAChE the relative decline in reactivity toward phosphonates (500–460-fold) differed from that toward the phosphates (12–95-fold). Although formation of Michaelis complexes with substrates does not seem to involve significant interaction with the oxyanion hole, interactions with this motif are a major stabilizing element in accommodation of covalent inhibitors like organophosphates or carbamates. These observations and molecular modeling suggest that replacements of residues Gly-120 or Gly-121 by alanine alter the structure of the oxyanion hole motif, abolishing the H-bonding capacity of residue at position 121. These mutations weaken the interaction between HuAChE and the various ligands by 2.7–5.0 kcal/mol. In contrast, variations in reactivity due to replacement of residue Gly-122 seem to result from steric hindrance at the active center acyl pocket.


Journal of Biological Chemistry | 1996

The Architecture of Human Acetylcholinesterase Active Center Probed by Interactions with Selected Organophosphate Inhibitors

Arie Ordentlich; Dov Barak; Chanoch Kronman; Naomi Ariel; Yoffi Segall; Baruch Velan; Avigdor Shafferman

The role of the functional architecture of human acetylcholinesterase (HuAChE) active center in facilitating reactions with organophosphorus inhibitors was examined by a combination of site-directed mutagenesis and kinetic studies of phosphorylation with organophosphates differing in size of their alkoxy substituents and in the nature of the leaving group. Replacements of residues Phe-295 and Phe-297, constituting the HuAChE acyl pocket, increase up to 80-fold the reactivity of the enzymes toward diisopropyl phosphorofluoridate, diethyl phosphorofluoridate, and p-nitrophenyl diethyl phosphate (paraoxon), indicating the role of this subsite in accommodating the phosphate alkoxy substituent. On the other hand, a decrease of up to 160-fold in reactivity was observed for enzymes carrying replacements of residues Tyr-133, Glu-202, and Glu-450, which are constituents of the hydrogen bond network in the HuAChE active center, which maintains its unique functional architecture. Replacement of residues Trp-86, Tyr-337, and Phe-338 in the alkoxy pocket affected reactivity toward diisopropyl phosphorofluoridate and paraoxon, but to a lesser extent that toward diethyl phosphorofluoridate, indicating that both the alkoxy substituent and the p-nitrophenoxy leaving group interact with this subsite. In all cases the effects on reactivity toward organophosphates, demonstrated in up to 10,000-fold differences in the values of bimolecular rate constants, were mainly a result of altered affinity of the HuAChE mutants, while the apparent first order rate constants of phosphorylation varied within a narrow range. This finding indicates that the main role of the functional architecture of HuAChE active center in phosphorylation is to facilitate the formation of enzyme-inhibitor Michaelis complexes and that this affinity, rather than the nucleophilic activity of the enzyme catalytic machinery, is a major determinant of HuAChE reactivity toward organophosphates.


The EMBO Journal | 1994

Electrostatic Attraction by Surface Charge does not Contribute to the Catalytic Efficiency of Acetylcholinesterase

Avigdor Shafferman; Arie Ordentlich; Dov Barak; C. Kronman; R Ber; Tamar Bino; Naomi Ariel; R Osman; B Velan

Acetylcholinesterases (AChEs) are characterized by a high net negative charge and by an uneven surface charge distribution, giving rise to a negative electrostatic potential extending over most of the molecular surface. To evaluate the contribution of these electrostatic properties to the catalytic efficiency, 20 single- and multiple-site mutants of human AChE were generated by replacing up to seven acidic residues, vicinal to the rim of the active-center gorge (Glu84, Glu285, Glu292, Asp349, Glu358, Glu389 and Asp390), by neutral amino acids. Progressive simulated replacement of these charged residues results in a gradual decrease of the negative electrostatic potential which is essentially eliminated by neutralizing six or seven charges. In marked contrast to the shrinking of the electrostatic potential, the corresponding mutations had no significant effect on the apparent bimolecular rate constants of hydrolysis for charged and non-charged substrates, or on the Ki value for a charged active center inhibitor. Moreover, the kcat values for all 20 mutants are essentially identical to that of the wild type enzyme, and the apparent bimolecular rate constants show a moderate dependence on the ionic strength, which is invariant for all the enzymes examined. These findings suggest that the surface electrostatic properties of AChE do not contribute to the catalytic rate, that this rate is probably not diffusion-controlled and that long-range electrostatic interactions play no role in stabilization of the transition states of the catalytic process.


FEBS Letters | 1993

Engineering resistance to ‘aging’ of phosphylated human acetylcholinesterase Role of hydrogen bond network in the active center

Arie Ordentlich; Chanoch Kronman; Dov Barak; Dana Stein; Naomi Ariel; Dino Marcus; Baruch Velan; Avigdor Shafferman

Recombinant human acetylcholinesterase (HuAChE) and selected mutants (E202Q, Y337A, E450A) were studied with respect to catalytic activity towards charged and noncharged substrates, phosphylation with organophosphorus (OP) inhibitors and subsequent aging of the OP‐conjugates. Amino acid E450, unlike residues E202 and Y337, is not within interaction distance from the active center. Yet, the bimolecular rates of catalysis and phosphylation are 30 100 fold lower for both E450A and E202Q compared to Y337A or the wild type and in both mutants the resulting OP‐conjugates show striking resistance to aging. It is proposed that a hydrogen bond network, that maintains the functional architecture of the active center, involving water molecules and residues E202 and E450, is responsible for the observed behaviour.


Molecular Pharmacology | 2006

Comparison of Polyethylene Glycol-Conjugated Recombinant Human Acetylcholinesterase and Serum Human Butyrylcholinesterase as Bioscavengers of Organophosphate Compounds

Ofer Cohen; Chanoch Kronman; Lily Raveh; Ohad Mazor; Arie Ordentlich; Avigdor Shafferman

Comparative protection studies in mice demonstrate that on a molar basis, recombinant human acetylcholinesterase (rHuAChE) confers higher levels of protection than native human butyrylcholinesterase (HuBChE) against organophosphate (OP) compound intoxication. For example, mice challenged with 2.5 LD50 of O-isopropyl methylphosphonofluoridate (sarin), pinacolylmethyl phosphonofluoridate (soman), and O-ethyl-S-(2-isopropylaminoethyl) methylphosphonothiolate (VX) after treatment with equimolar amounts of the two cholinesterases displayed 80, 100, and 100% survival, respectively, when pre-treatment was carried out with rHuAChE and 0, 20, and 60% survival, respectively, when pretreatment was carried out with HuBChE. Kinetic studies and active site titration analyses of the tested OP compounds with acetylcholinesterases (AChEs) and butyrylcholinesterases (BChEs) from different mammalian species demonstrate that the superior in vivo efficacy of acetyl-cholinesterases is in accordance with the higher stereoselectivity of AChE versus BChE toward the toxic enantiomers comprising the racemic mixtures of the various OP agents. In addition, we show that polyethylene glycol-conjugated (PEGy-lated) rHuAChE, which is characterized by a significantly extended circulatory residence both in mice and monkeys ( Biochem J357:795-802, 2001 ; Biochem J378:117-128, 2004 ), retains full reactivity toward OP compounds both in vitro and in vivo and provides a higher level of protection to mice against OP poisoning, compared with native serum-derived HuBChE. Indeed, PEGylated rHuAChE also confers superior prophylactic protection when administered intravenously or intramuscularly over 20 h before exposure of mice to a lethal dose of VX (1.3-1.5 LD50). These findings together with the observations that the PEGylated rHuAChE exhibits unaltered biodistribution and high bioavailability present a case for using PEGylated rHuAChE as a very efficacious bioscavenger of OP agents.


PLOS ONE | 2009

Isolation and chimerization of a highly neutralizing antibody conferring passive protection against lethal Bacillus anthracis infection.

Ronit Rosenfeld; Hadar Marcus; Einat Ben-Arie; Bat-El Lachmi; Adva Mechaly; Shaul Reuveny; Orit Gat; Ohad Mazor; Arie Ordentlich

Several studies have demonstrated that the passive transfer of protective antigen (PA)-neutralizing antibodies can protect animals against Bacillus anthracis infection. The standard protocol for the isolation of PA-neutralizing monoclonal antibodies is based upon a primary selection of the highest PA-binders by ELISA, and usually yields only few candidates antibodies. We demonstrated that by applying a PA-neutralization functionality-based screen as the primary criterion for positive clones, it was possible to isolate more than 100 PA-neutralizing antibodies, some of which exhibited no measurable anti-PA titers in ELISA. Among the large panel of neutralizing antibodies identified, mAb 29 demonstrated the most potent activity, and was therefore chimerized. The variable region genes of the mAb 29 were fused to human constant region genes, to form the chimeric 29 antibody (cAb 29). Guinea pigs were fully protected against infection by 40LD50 B. anthracis spores following two separate administrations with 10 mg/kg of cAb 29: the first administration was given before the challenge, and a second dose was administered on day 4 following exposure. Moreover, animals that survived the challenge and developed endogenous PA-neutralizing antibodies with neutralizing titers above 100 were fully protected against repeat challenges with 40LD50 of B. anthracis spores. The data presented here emphasize the importance of toxin neutralization-based screens for the efficient isolation of protective antibodies that were probably overlooked in the standard screening protocol. The protective activity of the chimeric cAb 29 demonstrated in this study suggest that it may serve as an effective immunotherapeutic agent against anthrax.


Vaccine | 2009

Effective post-exposure protection against lethal orthopoxviruses infection by vaccinia immune globulin involves induction of adaptive immune response

Shlomo Lustig; Galia Maik-Rachline; Nir Paran; Sharon Melamed; Tomer Israely; Noam Erez; Nadav Orr; Shaul Reuveny; Arie Ordentlich; Orgad Laub; Avigdor Shafferman; Baruch Velan

The therapeutic potential of human vaccinia immunoglobulin (VIG) in orthopoxvirus infection was examined using two mouse models for human poxvirus, based on Ectromelia virus and Vaccinia Western Reserve (WR) respiratory infections. Despite the relatively fast clearance of human VIG from mice circulation, a single VIG injection protected immune-competent mice against both infections. Full protection against lethal Ectromelia virus infection was achieved by VIG injection up to one day post-exposure, and even injection of VIG two or three days post-infection conferred solid protection (60-80%). Nevertheless, VIG failed to protect VACV-WR challenged immune-deficient mice, even though repeated injections prolonged SCID mice survival. These results suggest the involvement of host immunity in protection. VIG provides the initial protective time-window allowing induction of the adaptive response required to achieve complete protection. Additionally, VIG can be administered in conjunction with active Vaccinia-Lister vaccination. Vaccine efficiency is not impaired, providing a non-prohibitive VIG dose is used. Thus, VIG can be used as a prophylactic measure against post-vaccinal complications but could also serve for post-exposure treatment against smallpox.


FEBS Letters | 1996

Structural Modifications of the Ω Loop in Human Acetylcholinesterase

Baruch Velan; Dov Barak; Naomi Ariel; Moshe Leitner; Tamar Bino; Arie Ordentlich; Avigdor Shafferman

Conformational mobility of the surface Ω loop (Cys‐69‐Cys‐96) in human acetylcholinesterase (HuAChE) was recently implicated in substrate accessibility to the active center and in the mechanism of allosteric modulation of enzymatic activity. We therefore generated and kinetically evaluated the following modifications or replacements in HuAChE: (a) residues at the loop ends, (b) residues involved in putative hydrogen‐bond interactions within the loop and between the loop and the protein core, (c) ChEs conserved proline residues within the loop and (d) a deletion of a conserved segment of 5 residues. All the residue replacements, including those of the prolines, had either limited or no effect on enzyme reactivity. These results suggest that unlike the case of lipase, the Ω loop in the HuAChE is not involved in large lid‐like displacements. In cases where modifications of the loop sequence had some effect on reactivity, the effects could be attributed to an altered position of residue Trp‐86 supporting the proposed coupling between the structure of the Ω loop and the positioning of the Trp‐86 indole moiety, in catalytic activity and in allosterism.


Biochemical Journal | 2009

Accommodation of physostigmine and its analogues by acetylcholinesterase is dominated by hydrophobic interactions

Dov Barak; Arie Ordentlich; Dana Stein; Qian-sheng Yu; Avigdor Shafferman

The role of the functional architecture of the HuAChE (human acetylcholinesterase) in reactivity toward the carbamates pyridostigmine, rivastigmine and several analogues of physostigmine, that are currently used or considered for use as drugs for Alzheimers disease, was analysed using over 20 mutants of residues that constitute the interaction subsites in the active centre. Both steps of the HuAChE carbamylation reaction, formation of the Michaelis complex as well as the nucleophilic process, are sensitive to accommodation of the ligand by the enzyme. For certain carbamate/HuAChE combinations, the mode of inhibition shifted from a covalent to a noncovalent type, according to the balance between dissociation and covalent reaction rates. Whereas the charged moieties of pyridostigmine and rivastigmine contribute significantly to the stability of the corresponding HuAChE complexes, no such effect was observed for physostigmine and its analogues, phenserine and cymserine. Moreover, physostigmine-like ligands carrying oxygen instead of nitrogen at position -1 of the tricyclic moiety (physovenine and tetrahydrofurobenzofuran analogues) displayed comparable structure-function characteristics toward the various HuAChE enzymes. The essential role of the HuAChE hydrophobic pocket, comprising mostly residues Trp(86) and Tyr(337), in accommodating (-)-physostigmine and in conferring approximately 300-fold stereoselectivity toward physostigmines, was elucidated through examination of the reactivity of selected HuAChE mutations toward enantiomeric pairs of different physostigmine analogues. The present study demonstrates that certain charged and uncharged ligands, like analogues of physostigmine and physovenine, seem to be accommodated by the enzyme mostly through hydrophobic interactions.

Collaboration


Dive into the Arie Ordentlich's collaboration.

Top Co-Authors

Avatar

Avigdor Shafferman

Israel Institute for Biological Research

View shared research outputs
Top Co-Authors

Avatar

Baruch Velan

Israel Institute for Biological Research

View shared research outputs
Top Co-Authors

Avatar

Dov Barak

Israel Institute for Biological Research

View shared research outputs
Top Co-Authors

Avatar

Chanoch Kronman

Israel Institute for Biological Research

View shared research outputs
Top Co-Authors

Avatar

Naomi Ariel

Israel Institute for Biological Research

View shared research outputs
Top Co-Authors

Avatar

Yoffi Segall

Israel Institute for Biological Research

View shared research outputs
Top Co-Authors

Avatar

Dana Kaplan

Israel Institute for Biological Research

View shared research outputs
Top Co-Authors

Avatar

Dana Stein

Israel Institute for Biological Research

View shared research outputs
Top Co-Authors

Avatar

Ohad Mazor

Israel Institute for Biological Research

View shared research outputs
Top Co-Authors

Avatar

C. Kronman

Israel Institute for Biological Research

View shared research outputs
Researchain Logo
Decentralizing Knowledge