David E. Lenz scite author profile

Dangerous organophosphorus (OP) compounds have been used as insecticides in agriculture and in chemical warfare. Because exposure to OP could create a danger for humans in the future, butyrylcholinesterase (BChE) has been developed for prophylaxis to these chemicals. Because it is impractical to obtain sufficient quantities of plasma BChE to treat humans exposed to OP agents, the production of recombinant BChE (rBChE) in milk of transgenic animals was investigated. Transgenic mice and goats were generated with human BChE cDNA under control of the goat ␤-casein promoter. Milk from transgenic animals contained 0.1-5 g/liter of active rBChE. The plasma half-life of PEGylated, goat-derived, purified rBChE in guinea pigs was 7-fold longer than non-PEGylated dimers. The rBChE from transgenic mice was inhibited by nerve agents at a 1:1 molar ratio. Transgenic goats produced active rBChE in milk sufficient for prophylaxis of humans at risk for exposure to OP agents.organophosphorus nerve agent ͉ recombinant protein expression ͉ transgenic production H uman plasma butyrylcholinesterase (huBChE) (EC 3.1.1.8) is a globular, tetrameric serine esterase with a molecular mass of Ϸ340 kDa that is stable in plasma with a half-life of Ϸ12 days (1, 2). Although the physiological function of huBChE is unclear, the enzyme prevents intoxication of animals exposed to organophosphorus (OP) compounds (3, 4). The huBChE enzyme also hydrolyzes many ester-containing drugs, such as cocaine and succinylcholine (5). The toxicity of OP agents is due to irreversible inhibition of acetylcholinesterase and the subsequent continuous stimulation of neurons by acetylcholine (6). Administration of exogenous huBChE, which irreversibly binds OP agents to prevent inactivation of acetylcholinesterase and continuous cholinergic stimulation, is a potential strategy for preventing toxicity from OP agents (4). Although huBChE has been obtained from human plasma by a large scale purification technique, this procedure is severely limited by the volume of human plasma needed (7). It is unlikely that a sufficient amount of enzyme could be purified commercially by this technique. Because of the 1:1 stoichiometry required for protection against exposure to OP agents (8), large quantities of huBChE are needed for effective prophylaxis and treatment of exposure. Compared with other potential enzymatic bioscavengers of OP agents, huBChE has a broad spectrum of activity, a relatively long half-life, and limited, if any, physiological side effects (9). Producing recombinant BChE (rBChE) is an alternative to purification of the enzyme from human plasma. Recombinant huBChE has been expressed in Escherichia coli (10), albeit in a nonfunctional form; mammalian 293T (11); and CHO (12) cells. However, these expression systems cannot economically produce sufficient quantities of rBChE with a residence time similar to native huBChE that would allow development of the enzyme as an agent for prophylaxis against OP poisoning.The production of recombinant proteins by the mammary g...

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Stoichiometric and catalytic scavengers as protection against nerve agent toxicity: A mini review

Lenz

et al. 2007

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Plant-derived human butyrylcholinesterase, but not an organophosphorous-compound hydrolyzing variant thereof, protects rodents against nerve agents

Geyer

Kannan

Garnaud

et al. 2010

Proc. Natl. Acad. Sci. U.S.A.

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The concept of using cholinesterase bioscavengers for prophylaxis against organophosphorous nerve agents and pesticides has progressed from the bench to clinical trial. However, the supply of the native human proteins is either limited (e.g., plasma-derived butyrylcholinesterase and erythrocytic acetylcholinesterase) or nonexisting (synaptic acetylcholinesterase). Here we identify a unique form of recombinant human butyrylcholinesterase that mimics the native enzyme assembly into tetramers; this form provides extended effective pharmacokinetics that is significantly enhanced by polyethylene glycol conjugation. We further demonstrate that this enzyme (but not a G117H/E197Q organophosphorus acid anhydride hydrolase catalytic variant) can prevent morbidity and mortality associated with organophosphorous nerve agent and pesticide exposure of animal subjects of two model species.countermeasures | nonconventional warfare agents | organophosphorous pesticides | protein engineering | transgenic plants B utyrylcholinesterase (BChE) is the major cholinesterase (ChE) in the serum of humans (1, 2). Although the closely related enzyme acetylcholinesterase (AChE) is well described as the primary synaptic regulator of cholinergic transmission, a definitive physiological role for BChE has not yet been demonstrated (3). BChE is catalytically promiscuous and hydrolyzes not only acetylcholine (ACh), but also longer-chain choline esters (e.g., butyrylcholine, its preferred substrate, and succinylcholine) and a variety of non-choline esters, such as acetylsalicylic acid (aspirin) and cocaine (4, 5). Moreover, BChE binds most environmentally occurring ChE inhibitors as well as man-made organophosphorous (OP) pesticides and nerve agents (NAs) (6, 7-10).The systemic biodistribution and affinity for ChE inhibitors allow endogenous BChE to provide broad-spectrum protection against various toxicants by their sequestration before they reach cholinergic synapses. However, under realistic high-dose exposure scenarios, BChE serum levels are too low to afford adequate protection, resulting in persistent cholinergic excitation due to irreversible inhibition of AChE and subsequent accumulation of ACh. Sublethal manifestations of this state include unregulated exocrine secretion and gastrointestinal hypermotility. Death usually results from unregulated stimulation at neuromuscular junction leading to hemodynamic instability and tetanic contraction of the respiratory muscles (11,12).Current OP poisoning therapy consists of atropine for muscarinic ACh receptor blockade and diazepam for symptomatic management of convulsions (12). Additionally, oxime therapy with 2-pralidoxime (2-PAM) can effectively reactivate some but not all OP-AChE adducts (13)(14)(15). This standard therapeutic approach can reduce mortality, but insufficiently prevents the incapacitation associated with OP toxicity (12, 16).Prophylaxis by administration of exogenous ChEs has proven successful in reducing OP-associated morbidity and mortality, but requires the availability of rel...

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Structure/function analyses of human serum paraoxonase (HuPON1) mutants designed from a DFPase-like homology model

Yeung¹,

Josse

Nicholson³

et al. 2004

Biochimica et Biophysica Acta (BBA) - Proteins and Proteomics

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and Cerasoli, Douglas M., "Structure/function analyses of human serum paraoxonase (HuPON1) mutants designed from a DFPaselike homology model" (2004 AbstractHuman serum paraoxonase (HuPON1) is a calcium-dependent enzyme that hydrolyzes esters, including organophosphates and lactones, and exhibits anti-atherogenic properties. A few amino acids have been shown to be essential for the enzyme's arylesterase and organophosphatase activities. Until very recently, a three-dimensional model was not available for HuPON1, so functional roles have not been assigned to those residues. Based on sequence-structure alignment studies, we have folded the amino acid sequence of HuPON1 onto the sixfold h-propeller structure of squid diisopropylfluorophosphatase (DFPase). We tested the validity of this homology model by circular dichroism (CD) spectroscopy and site-directed mutagenesis. Consistent with predictions from the homology model, CD data indicated that the structural composition of purified HuPON1 consists mainly of h-sheets. Mutants of HuPON1 were assayed for enzymatic activity against phenyl acetate and paraoxon. Substitution of residues predicted to be important for substrate binding (L69, H134, F222, and C284), calcium ion coordination (D54, N168, N224, and D269), and catalytic mechanism of HuPON1 (H285) led to enzyme inactivation. Mutants F222Y and H115W exhibited substrate-binding selectivity towards phenyl acetate and paraoxon, respectively. The homology model presented here is very similar to the recently obtained PON1 crystal structure, and has allowed identification of several residues within the enzyme active site. D

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Protection against soman or VX poisoning by human butyrylcholinesterase in guinea pigs and cynomolgus monkeys

Lenz¹,

Maxwell²,

Koplovitz³

et al. 2005

Chemico-Biological Interactions

113

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Bioscavenger for Protection From Toxicity of Organophosphorus Compounds

Saxena

Sun

Luo

et al. 2006

JMN

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Current antidotal regimens for organophosphorus compound (OP) poisoning consist of a combination of pretreatment with a spontaneously reactivating AChE inhibitor such as pyridostigmine bromide, and postexposure therapy with anticholinergic drugs such as atropine sulfate and oximes such as 2-PAM chloride (Gray, 1984). Although these antidotal regimens are effective in preventing lethality of animals from OP poisoning, they do not prevent postexposure incapacitation, convulsions, performance deficits, or, in many cases, permanent brain damage (Dunn and Sidell, 1989). These problems stimulated the development of enzyme bioscavengers as a pretreatment to sequester highly toxic OPs before they reach their physiological targets. Several studies over the last two decades have demonstrated that exogenously administered human serum butyrylcholinesterase (Hu BChE) can be used successfully as a safe, efficacious, and single prophylactic treatment to counteract the toxicity of OPs. It also has potential use for first responders (civilians) reacting to terrorist nerve gas release, pesticide overexposure, or succinylcholine-induced apnea. A dose of 200 mg of Hu BChE in humans is envisioned as a prophylactic treatment that can protect from exposure of 2-5 x LD50 of nerve agents (Ashani, 2000).

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The Role of Glutamate-199 in the Aging of Cholinesterase

Saxena

Doctor²,

Maxwell³

et al. 1993

Biochemical and Biophysical Research Communications

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Dramatic Differences in Organophosphorus Hydrolase Activity between Human and Chimeric Recombinant Mammalian Paraoxonase-1 Enzymes

Otto

Harsch²,

Yeung

et al. 2009

Biochemistry

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Human serum paraoxonase-1 (HuPON1) has the capacity to hydrolyze aryl esters, lactones, oxidized phospholipids, and organophosphorus (OP) compounds. HuPON1 and bacterially expressed chimeric recombinant PON1s (G2E6 and G3C9) differ by multiple amino acids, none of which are in the putative enzyme active site. To address the importance of these amino acid differences, the abilities of HuPON1, G2E6, G3C9, and several variants to hydrolyze phenyl acetate, paraoxon, and V-type OP nerve agents were examined. HuPON1 and G2E6 have a ten-fold greater catalytic efficiency toward phenyl acetate than G3C9. In contrast, bacterial PON1s are better able to promote hydrolysis of paraoxon, whereas HuPON1 is considerably better at catalyzing the hydrolysis of the nerve agents VX and VR. These studies demonstrate that mutations distant from the active site of PON1 have large and unpredictable effects on the substrate specificities and possibly the hydrolytic mechanisms of HuPON1, G2E6, and G3C9. The replacement of residue H115 in the putative active site with tryptophan (H115W) has highly disparate effects on HuPON1 and G2E6. In HuPON1, variant H115W loses the ability to hydrolyze VR but has improved activity toward paraoxon and VX. The H115W variant of G2E6 has similar paraoxonase activity to wild type G2E6, modest activity with phenyl acetate and VR, and increased VX hydrolysis. VR inhibits H115W HuPON1 competitively when paraoxon is the substrate and non-competitively when VX is the substrate. We have identified the first variant of HuPON1, H115W, that displays significantly enhanced catalytic activity against an authentic V-type nerve agent.Organophosphorus (OP) nerve agents are among the most toxic chemical substances identified (1). These compounds exert toxicity by readily binding to acetylcholinesterase (AChE) at the active site serine and inhibiting the ability of AChE to terminate cholinergic nerve transmissions (2).

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David E. Lenz

Recombinant human butyrylcholinesterase from milk of transgenic animals to protect against organophosphate poisoning

Stoichiometric and catalytic scavengers as protection against nerve agent toxicity: A mini review

Plant-derived human butyrylcholinesterase, but not an organophosphorous-compound hydrolyzing variant thereof, protects rodents against nerve agents

Structure/function analyses of human serum paraoxonase (HuPON1) mutants designed from a DFPase-like homology model

Protection against soman or VX poisoning by human butyrylcholinesterase in guinea pigs and cynomolgus monkeys

Bioscavenger for Protection From Toxicity of Organophosphorus Compounds

The Role of Glutamate-199 in the Aging of Cholinesterase

Dramatic Differences in Organophosphorus Hydrolase Activity between Human and Chimeric Recombinant Mammalian Paraoxonase-1 Enzymes

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