Effect of human acetylcholinesterase subunit assembly on its circulatory residence

Cellular and Molecular Engineering of Glycan Sialylation in Heterologous Systems

Glycans have been shown to play a key role in many biological processes, such as signal transduction, immunogenicity, and disease progression. Among the various glycosylation modifications found on cell surfaces and in biomolecules, sialylation is especially important, because sialic acids are typically found at the terminus of glycans and have unique negatively charged moieties associated with cellular and molecular interactions. Sialic acids are also crucial for glycosylated biopharmaceutics, where they promote stability and activity. In this regard, heterogenous sialylation may produce variability in efficacy and limit therapeutic applications. Homogenous sialylation may be achieved through cellular and molecular engineering, both of which have gained traction in recent years. In this paper, we describe the engineering of intracellular glycosylation pathways through targeted disruption and the introduction of carbohydrate active enzyme genes. The focus of this review is on sialic acid-related genes and efforts to achieve homogenous, humanlike sialylation in model hosts. We also discuss the molecular engineering of sialyltransferases and their application in chemoenzymatic sialylation and sialic acid visualization on cell surfaces. The integration of these complementary engineering strategies will be useful for glycoscience to explore the biological significance of sialic acids on cell surfaces as well as the future development of advanced biopharmaceuticals.

Polyproline-rich peptides associated with Torpedo californica acetylcholinesterase tetramers

Acetylcholinesterase (AChE) terminates cholinergic neurotransmission by hydrolyzing acetylcholine. The collagen-tailed AChE tetramer is a product of 2 genes, ACHE and ColQ. The AChE tetramer consists of 4 identical AChE subunits and one polyproline-rich peptide, whose function is to hold the 4 AChE subunits together. Our goal was to determine the amino acid sequence of the polyproline-rich peptide(s) in Torpedo californica AChE (TcAChE) tetramers to aid in the analysis of images that will be acquired by cryo-EM. Collagen-tailed AChE was solubilized from Torpedo californica electric organ, converted to 300 kDa tetramers by digestion with trypsin, and purified by affinity chromatography. Polyproline-rich peptides were released by denaturing the TcAChE tetramers in a boiling water bath, and reducing disulfide bonds with dithiothreitol. Carbamidomethylated peptides were separated from TcAChE protein on a spin filter before they were analyzed by liquid chromatography tandem mass spectrometry on a high resolution Orbitrap Fusion Lumos mass spectrometer. Of the 64 identified collagen-tail (ColQ) peptides, 60 were from the polyproline-rich region near the N-terminus of ColQ. The most abundant proline-rich peptides were SVNKCCLLTPPPPPMFPPPFFTETNILQE, at 40% of total mass-spectral signal intensity, and SVNKCCLLTPPPPPMFPPPFFTETNILQEVDLNNLPLEIKPTEPSCK, at 27% of total intensity. The high abundance of these 2 peptides makes them candidates for the principal form of the polyproline-rich peptide in the trypsin-treated TcAChE tetramers.

Cholinesterases and the fine line between poison and remedy

Acetylcholinesterase (AChE, EC 3.1.1.7) and butyrylcholinesterase (BChE, EC 3.1.1.8) are related enzymes found across the animal kingdom. The critical role of acetylcholinesterase in neurotransmission has been known for almost a century, but a physiological role for butyrylcholinesterase is just now emerging. The cholinesterases have been deliberately targeted for both therapy and toxicity, with cholinesterase inhibitors being used in the clinic for a variety of disorders and conversely for their toxic potential as pesticides and chemical weapons. Non-catalytic functions of the cholinesterases (ChEs) participate in both neurodevelopment and disease. Manipulating either the catalytic activities or the structure of these enzymes can potentially shift the balance between beneficial and adverse effect in a wide number of physiological processes.

Biogenesis, assembly and trafficking of acetylcholinesterase

Acetylcholinesterase (AChE) is expressed as several homomeric and heterooligomeric forms in a wide variety of tissues such as neurons in the central and peripheral nervous systems and their targets including skeletal muscle, endocrine and exocrine glands. In addition, glycolipid-anchored forms are expressed in erythropoietic and lymphopoietic cells. While transcriptional and post-transcriptional regulation is important for determining which AChE oligomeric forms are expressed in a given tissue, translational and post-translational regulatory mechanisms at the level of protein folding, assembly and sorting play equally important roles in assuring that the AChE molecules reach their intended sites on the cell surface in the appropriate numbers. This brief review will focus on the latter events in the cell with the goal of providing novel therapeutic interventional strategies for the treatment of organophosphate and carbamate pesticide and nerve agent exposure. This is an article for the special issue XVth International Symposium on Cholinergic Mechanisms.

Rescue and Stabilization of Acetylcholinesterase in Skeletal Muscle by N-terminal Peptides Derived from the Noncatalytic Subunits

The vast majority of newly synthesized acetylcholinesterase (AChE) molecules do not assemble into catalytically active oligomeric forms and are rapidly degraded intracellularly by the endoplasmic reticulum-associated protein degradation pathway. We have previously shown that AChE in skeletal muscle is regulated in part post-translationally by the availability of the noncatalytic subunit collagen Q, and others have shown that expression of a 17-amino acid N-terminal proline-rich attachment domain of collagen Q is sufficient to promote AChE tetramerization in cells producing AChE. In this study we show that muscle cells, or cell lines expressing AChE catalytic subunits, incubated with synthetic proline-rich attachment domain peptides containing the endoplasmic reticulum retrieval sequence KDEL take up and retrogradely transport them to the endoplasmic reticulum network where they induce assembly of AChE tetramers. The peptides act to enhance AChE folding thereby rescuing them from reticulum degradation. This enhanced folding efficiency occurs in the presence of inhibitors of protein synthesis and in turn increases total cell-associated AChE activity and active tetramer secretion. Pulse-chase studies of isotopically labeled AChE molecules show that the enzyme is rescued from intracellular degradation. These studies provide a mechanistic explanation for the large scale intracellular degradation of AChE previously observed and indicate that simple peptides alone can increase the production and secretion of this critical synaptic enzyme in muscle tissue.

Strategies for Engineering Protein N-Glycosylation Pathways in Mammalian Cells

Complexity and heterogeneity of oligosaccharides present a considerable challenge to the biopharmaceutical industry to manufacture biotherapeutics with reproducible and consistent glycoform profiles. Mammalian cells, especially Chinese hamster ovary cells, are the most widely used platform for the production of biotherapeutics. The glycans produced are predominantly of the complex type, with some differences between human and nonhuman mammalian glycosylation existing. This review briefly summarizes metabolic glyco-engineering strategies used in mammalian cells in order to alter the glycosylation patterns attached to proteins applied for diverse biotechnology applications.

The proline-rich tetramerization peptides in equine serum butyrylcholinesterase

Soluble, tetrameric, plasma butyrylcholinesterase from horse has previously been shown to include a non-covalently attached polyproline peptide in its structure. The polyproline peptide matched the polyproline-rich region of human lamellipodin. Our goal was to examine the tetramer-organizing peptides of horse butyrylcholinesterase in more detail. Horse butyrylcholinesterase was denatured by boiling, thus releasing a set of polyproline peptides ranging in mass from 1173 to 2098 Da. The peptide sequences were determined by fragmentation in MALDI-TOF-TOF and linear ion trap quadrupole Orbitrap mass spectrometers. Twenty-seven polyproline peptides grouped into 13 families were identified. Peptides contained a minimum of 11 consecutive proline residues and as many as 21. Many of the peptides had a non-proline amino acid at the N-terminus. A search of the protein databanks matched peptides to nine proteins, although not all peptides matched a known protein. It is concluded that polyproline peptides of various lengths and sequences are included in the tetramer structure of horse butyrylcholinesterase. The function of these polyproline peptides is to serve as tetramer-organizing peptides.

Respective roles of the catalytic domains and C-terminal tail peptides in the oligomerization and secretory trafficking of human acetylcholinesterase and butyrylcholinesterase

Butyrylcholinesterase (BChE) and the T splice variant of acetylcholinesterase that is predominant in mammalian brain and muscles (AChE(T)) possess a characteristic C-terminal tail (t) peptide. This t peptide allows their assembly into tetramers associated with the anchoring proteins ColQ and PRiMA. Although the t peptides of all vertebrate cholinesterases are remarkably similar and, in particular, contain seven strictly conserved aromatic residues, these enzymes differ in some of their oligomerization properties. To explore these differences, we studied human AChE (Aa) and BChE (Bb), and chimeras in which the t peptides (a and b) were exchanged (Ab and Ba). We found that secretion was increased by deletion of the t peptides, and that it was more efficient with a than with b. The patterns of oligomers were similar for Aa and Ab, as well as for Ba and Bb, indicating a predominant influence of the catalytic domains. However, addition of a cysteine within the aromatic-rich segment of the t peptides modified the oligomeric patterns: with a cysteine at position 19, the proportion of tetramers was markedly increased for Aa(S19C) and Ba(S19C), and to a lesser extent for Bb(N19C); the Ab(N19C) mutant produced all oligomeric forms, from monomers to hexamers. These results indicate that both the catalytic domains and the C-terminal t peptides contribute to the capacity of cholinesterases to form and secrete various oligomers. Sequence comparisons show that the differences between the t peptides of AChE and BChE are remarkably conserved among all vertebrates, suggesting that they reflect distinct functional adaptations.

Aging-resistant organophosphate bioscavenger based on polyethylene glycol-conjugated F338A human acetylcholinesterase

The high reactivity of cholinesterases (ChEs) toward organophosphorus (OP) compounds has led to propose recombinant ChEs as bioscavengers of nerve agents. The bioscavenging potential of recombinant ChEs can be enhanced by conjugation of polyethylene glycol (PEG) moieties, to extend their circulatory residence. However, the ability of exogenously administered ChEs to confer long-term protection against repeated exposures to nerve agents is still limited due to the aging process, whereby organophosphate-ChE adducts undergo irreversible dealkylation, which precludes oxime-mediated reactivation of the enzyme. To generate an optimal acetylcholinesterase (AChE)-based OP bioscavenger, the F338A mutation, known to decelerate the rate of aging of AChE-OP conjugates, was incorporated into polyethylene glycol-conjugated (PEGylated) human AChE. The PEGylated F338A-AChE displayed unaltered rates of hydrolysis, inhibition, phosphylation, and reactivation and could effectively protect mice against exposure to soman (pinacolylmethyl phosphonofluoridate), sarin (O-isopropyl methylphosphonofluoridate), or O-ethyl-S-(2-isopropylaminoethyl) methylphosphonothioate (VX). Unlike PEGylated wild-type (WT)-AChE, the PEGylated F338A-AChE exhibits significantly reduced aging rates after soman inhibition and can be efficiently reactivated by the 1-[[[4(aminocarbonyl)-pyridinio]methoxy]methyl]-2(hydroxyimino)methyl]pyridinium dichloride (HI-6) oxime, both in vitro and in vivo. Accordingly, oxime administration to PEG-F338A-AChE-pretreated mice enabled them to withstand repeated soman exposure (5.4 and 4 LD(50)/dose), whereas same regime treatment of non-PEGylated F338A-AChE- or PEGylated WT-AChE-pretreated mice failed to protect against the second challenge, due to rapid clearance or irreversible aging of the latter enzymes. Thus, judicious incorporation of selected mutations into the AChE mold in conjunction with its chemical modification provides means to engineer an optimal ChE-based OP bioscavenger in terms of circulatory longevity, resistance to aging, and reduced doses required for protection, even against repeated exposures to nerve agents, such as soman.

Crystallization and X-ray structure of full-length recombinant human butyrylcholinesterase

Human butyrylcholinesterase (BChE) has been shown to function as an endogenous scavenger of diverse poisons. BChE is a 340 kDa tetrameric glycoprotein that is present in human serum at a concentration of 5 mg l(-1). The well documented therapeutic effects of BChE on cocaine toxicity and organophosphorus agent poisoning has increased the need for effective methods of producing recombinant therapeutic BChE. In order to be therapeutically useful, BChE must have a long circulatory residence time or associate as tetramers. Full-length recombinant BChE produced in Chinese hamster ovary (CHO) cells or human embryonic kidney cells has been shown to associate as monomers, with a shorter circulatory residence time than the naturally occurring tetrameric serum protein. Based on the preceding observation as well as the need to develop novel methodologies to facilitate the mass production of therapeutic recombinant BChE, studies have been initiated to determine the structural basis of tetramer formation. Towards these ends, full-length monomeric recombinant BChE has been crystallized for the first time. A 2.8 A X-ray structure was solved in space group P42(1)2, with unit-cell parameters a = b = 156, c = 146 A.

Polyethylene-glycol conjugated recombinant human acetylcholinesterase serves as an efficacious bioscavenger against soman intoxication

Extensive pharmacokinetic studies in both mice and rhesus macaques, with biochemically well defined forms of native and recombinant AChEs from bovine, rhesus and human origin, allowed us to determine an hierarchical pattern by which post-translation-related factors and specific amino-acid epitopes govern the pharmacokinetic performance of the enzyme molecule. In parallel, we demonstrated that controlled conjugation of polyethylene-glycol (PEG) side-chains to lysine residues of rHuAChE also results in the generation of active enzyme with improved pharmacokinetic performance. Here, we show that equally efficient extension of circulatory residence can be achieved by specific conditions of PEGylation, regardless of the post-translation-modification state of the enzyme. The masking effect of PEGylation, which is responsible for extending circulatory lifetime, also contributes to the elimination of immunological responses following repeated administration of AChE. Finally, in vivo protection studies in mice allowed us to determine that the PEGylated AChE protects the animal from a high lethal dose (2.5 LD(50)) of soman. On a mole basis, both the recombinant AChE and its PEGylated form provide higher levels of protection against soman poisoning than the native serum-derived HuBChE. The findings that circulatory long-lived PEGylated AChE can confer superior protection to mice against OP-compound poisoning while exhibiting reduced immunogenicity, suggest that this chemically modified version of rHuAChE may serve as a highly effective bioscavenger for prophylactic treatment against OP-poisoning.

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

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 J 357: 795-802, 2001 ; Biochem J 378: 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.

Amino acid domains control the circulatory residence time of primate acetylcholinesterases in rhesus macaques (Macaca mulatta)

An array of 13 biochemically well defined molecular forms of bovine, human and newly cloned rhesus macaque (Macaca mulatta) AChEs (acetylcholinesterases) differing in glycosylation and subunit assembly status were subjected to comparative pharmacokinetic studies in mice and rhesus macaques. The circulatory lifetimes of recombinant bovine, macaque and human AChEs in mice were governed by previously determined hierarchical rules; the longest circulatory residence time was obtained when AChE was fully sialylated and tetramerized [Kronman, Chitlaru, Elhanany, Velan and Shafferman (2000) J. Biol. Chem. 275, 29488-29502; Chitlaru, Kronman, Velan and Shafferman (2001) Biochem. J. 354, 613-625]. In rhesus macaques, bovine molecular forms still obeyed the same hierarchical rules, whereas primate AChEs showed significant deviation from this behaviour. Residence times of human and rhesus AChEs were effectively extended by extensive sialylation, but subunit tetramerization and N-glycan addition had a marginal effect on their circulatory longevity in macaques. It appears that the major factor responsible for the differential pharmacokinetics of bovine and primate AChEs in macaques is related to differences in primary structure, suggesting the existence of a specific mechanism for the circulatory clearance of primate AChEs in rhesus macaques. The 35 amino acids that differ between bovine and primate AChEs are clustered within three defined domains, all located at the enzyme surface, and may therefore mediate the facilitated removal of primate cholinesterases specifically from the circulation of monkeys. These surface domains can be effectively masked by poly(ethylene glycol) appendage, resulting in the generation of chemically modified human and macaque AChEs that reside in the circulation for extraordinarily long periods of time (mean residence time of 10000 min). This extended residence time is similar to that displayed by native macaque butyrylcholinesterase (9950 min), which is the prevalent cholinesterase form in the circulation of adult macaques.

Overloading and removal of N-glycosylation targets on human acetylcholinesterase: effects on glycan composition and circulatory residence time

Optimization of post-translational modifications was shown to affect the ability of recombinant human acetylcholinesterase (rHuAChE) produced in HEK-293 cells to be retained in the circulation for prolonged periods of time [Kronman, Velan, Marcus, Ordentlich, Reuveny and Shafferman (1995) Biochem. J. 311, 959-967; Chitlaru, Kronman, Zeevi, Kam, Harel, Ordentlich, Velan and Shafferman (1998) Biochem. J. 336, 647-658; Chitlaru, Kronman, Velan and Shafferman (2001) Biochem. J. 354, 613-625]. To evaluate the possible contribution of the number of appended N-glycans in determining the pharmacokinetic behaviour of AChE, a series of sixteen recombinant human AChE glycoforms, differing in their number of appended N-glycans (2, 3, 4 or 5 glycans), state of assembly (dimeric or tetrameric) and terminal glycan sialylation (partially or fully sialylated) were generated. Extensive structural analysis of N-glycans demonstrated that the various glycan types associated with all the different rHuAChE glycoforms are essentially similar both in structure and abundance, and that production of the various glycoforms in the sialyltransferase-overexpressing 293ST-2D6 cell line resulted in the generation of enzyme species that carry glycans sialylated to the same extent. Pharmacokinetic profiling of the rHuAChE glycoforms in their fully tetramerized and sialylated state clearly demonstrated that circulatory longevity correlated directly with the number of attached N-glycans (mean residence times for rHuAChE glycoforms harbouring 2, 3, and 4 glycans=200, 740, and 1055 min respectively). This study provides evidence that glycan loading, together with N-glycan terminal processing and enzyme subunit oligomerization, operate in a hierarchical and concerted manner in determining the pharmacokinetic characteristics of AChE.

Effect of chemical modification of recombinant human acetylcholinesterase by polyethylene glycol on its circulatory longevity

Post-translational modifications were recently shown to be responsible for the short circulatory mean residence time (MRT) of recombinant human acetylcholinesterase (rHuAChE) [Kronman, Velan, Marcus, Ordentlich, Reuveny and Shafferman (1995) Biochem. J. 311, 959--967; Chitlaru, Kronman, Zeevi, Kam, Harel, Ordentlich, Velan and Shafferman (1998) Biochem. J. 336, 647--658; Chitlaru, Kronman, Velan and Shafferman (2001) Biochem. J. 354, 613--625], which is one of the major obstacles to the fulfilment of its therapeutic potential as a bioscavenger. In the present study we demonstrate that the MRT of rHuAChE can be significantly increased by the controlled attachment of polyethylene glycol (PEG) side chains to lysine residues. Attachment of as many as four PEG molecules to monomeric rHuAChE had minimal effects, if any, on either the catalytic activity (K(m)=0.09 mM and k(cat)=3.9 x 10(5) min(-1)) or the reactivity of the modified enzyme towards active-centre inhibitors, such as edrophonium and di-isopropyl fluorophosphate, or to peripheral-site ligands, such as propidium, BW284C51 and even the bulky snake-venom toxin fasciculin-II. The increase in MRT of the PEG-modified monomeric enzyme is linearly dependent, in the tested range, on the number of attached PEG molecules, as well as on their size. It appears that even low level PEG-conjugation can overcome the deleterious effect of under-sialylation on the pharmacokinetic performance of rHuAChE. At the highest tested ratio of attached PEG-20000/rHuAChE (4:1), an MRT of over 2100 min was attained, a value unmatched by any other known form of recombinant or native serum-derived AChE reported to date.