Unusual catalytic activities and functions of cholinesterases

Cholinesterases (acetylcholinesterase and butyrylcholinesterase) have been shown to exhibit not only esterase activity but also an amine sensitive aryl acylamidase and a metallo-carboxypeptidase activities. There is also evidence to indicate that they have functions in the substantia nigra of brain, in neural cell differentiation, cell division and tumorigenesis, cell-adhesion and detoxication mechanisms. Butyrylcholinesterase is suggested to act as a back-up enzyme in acetylcholinesterase knock-out mice. Cholinesterases have catalytic or non-catalytic roles in these functions. Partial sequence homology to many other proteins having different functions and a metal binding site which can influence functions are probably factors that confer the non-cholinergic functions and activities on cholinesterases.     

乙酰胆碱酯酶的非经典功能及其与A1zheimer's疾病的关系

乙酰胆碱酯酶（acetylcholinesterase,AChE)是主要存在于神经系统的一种水解酶,其经典功能是水解神经递质乙酰胆碱,从而终止神经冲动的传递。但是近年来,研究者发现许多证据表明它具有“非经典”的新功能,引起了人们的关注。除了水解神经递质乙酰胆碱的经典功能外,AChE对神经细胞的分化、迁移,突触的形成,造血系细胞和肿瘤细胞的增殖与分化调控也有作用。最近的研究结果显示：AChE可能在细胞凋亡过程中起重要作用,这对于认识Alzheimer‘s疾病（AD）的发病机理又有新的进步。     

The effect of acetylcholinesterase on outgrowth of dopaminergic neurons in organotypic slice culture of rat mid-brain

This study has investigated the possibility that acetylcholinesterase could play a non-classical role as an adhesion factor or growth factor in the development of dopaminergic neurons in organotypic slice culture of postnatal day 1 rats. When the culture medium was supplemented with acetylcholinesterase (3 U/ml), outgrowth of tyrosine hydroxylase-immunoreactive neurites was significantly enhanced. Addition of a specific inhibitor of acetylcholinesterase, BW284c51, caused a decrease in the number of tyrosine hydroxylase neurons and a reduction in the cell body size and extent of neurite outgrowth of remaining neurons. However, echothiophate which also inhibits AChE activity, did not produce these effects. Therefore acetylcholinesterase could act as a growth enhancing factor for dopaminergic neurons, and disruption of an as yet unidentified site on the acetylcholinesterase molecule by BW284c51 could decrease the survival and outgrowth of these neurons.     

The early phase of apoptosis in human neuroblastoma CHP100 cells is characterized by lipoxygenase-dependent ultraweak light emission

There is accumulating evidence that acetylcholinesterase has secondary noncholinergic functions, related to adhesion, differentiation, and the deposition of beta-amyloid in Alzheimer's disease. We have observed that the specific acetylcholinesterase peripheral anionic site inhibitors, BW284c51 and propidium iodide, abrogated cell-substrate adhesion in three human neuroblastoma cell lines. The active-site inhibitors, eserine and edrophonium, in contrast, had no effect. Certain anti-AChE antibodies were also shown to inhibit adhesion. Of these, the most effective were a monoclonal (E8) and a polyclonal having cholinesterase-like catalytic activity. These were raised against an acetylcholinesterase-inhibitor complex, implying that the epitope is associated with active-site structures. Two other monoclonal antibodies (E62A1 and E65E8) partially inhibited adhesion. The epitopes of these antibodies have been shown to overlap the peripheral anionic site of acetylcholinesterase. Competition ELISA between the monoclonal antibodies and inhibitors indicated competition between E8, E62A1, and E65E8 and the peripheral-site inhibitors BW284c51 and propidium, but not with the active-site inhibitors eserine and edrophonium. Fluorescence titration between antibodies and propidium confirmed these results. We conclude that the adhesion function of acetylcholinesterase is located at the peripheral anionic site. This has implications, not only for our understanding of neural development and its disorders, but also for the treatment of neuroblastoma, the leukemias, and Alzheimer's disease.     

Orchestrating brain-cell renewal: the role of immune cells in adult neurogenesis in health and disease

Immune cells and immune molecules have recently been shown to support neurogenesis from neural stem and progenitor cells in the adult brain. This non-classical immune activity takes place constantly under normal physiological conditions and is extended under acute pathological conditions to include the attraction of progenitor cells and induction of neurogenesis in regions of the adult central nervous system (CNS) in which formation of new neurons does not normally occur. We suggest that the immune system should be viewed as a novel player in the adult neural stem cell niche and a coordinator of cell renewal processes after injury. We discuss these notions in light of the well-known facts that both immune-cell activity and cell renewal are inherently limited in the adult CNS and that immune and stem cells provide the body's mechanisms of repair.     

Cranial nerve growth in birds is preceded by cholinesterase expression during neural crest cell migration and the formation of an HNK-1 scaffold

Summary The expression of the neural crest cell (NCC) markers acetylcholinesterase (AChE) and the HNK-1-epitope is compared from the emigration of cephalic NCC until the formation of the cranial nerves V-X in chicken and quail hindbrain. We show that NCC transiently express acetylcholinesterase (AChE) activity during their emigration; NCC migrate into butyrylcholinesterase (BChE)-positive areas of the cranial mesenchyme. Along these migratory tracks that foreshadow the course of later projecting cranial nerves, BChE increases strongly in cells that may represent immature Schwann cells. Both AChE and BChE, but not HNK-1, are expressed in the ectodermal placodes. In NCC, HNK-1 is expressed strongly only when they approach their destination sites. Their intense expression of HNK-1 then leads to the establishment of tunnel-shaped HNK-1 matrices, within which G4-positive cranial neurites begin to extend. We conclude that AChE and HNK-1 expression in cephalic NCC serve different functions, since AChE is related to their migration, and HNK-1 to their aggregation and the formation of an extracellular neurite scaffold.     

Plasma membrane microdomains: Organization,function and trafficking (Review)

The plasma membrane consists of a mosaic of functional microdomains facilitating a variety of physiological processes associated with the cell surface. In most cells, the majority of the cell surface is morphologically featureless, leading to difficulties in characterizing its organization and microdomain composition. The reliance on indirect and perturbing techniques has led to vigorous debate concerning the nature and even existence of some microdomains. Recently, increasing technical sophistication has been applied to study cell surface compartmentalization providing evidence for small, short-lived clusters that may be much less than 50 nm in diameter. Lipid rafts and caveolae are cholesterol-dependent, highly ordered microdomains that have received most attention in recent years, yet their precise roles in regulating functions such as cell signalling remain to be determined. Endocytosis of lipid rafts/caveolae follows a clathrin-independent route to both early endosomes and non-classical caveosomes. The observation that a variety of cellular pathogens localize to and internalize with these microdomains provides an additional incentive to characterize the organization, dynamics and functions of these domains.     

Plasma membrane microdomains: organization, function and trafficking

The plasma membrane consists of a mosaic of functional microdomains facilitating a variety of physiological processes associated with the cell surface. In most cells, the majority of the cell surface is morphologically featureless, leading to difficulties in characterizing its organization and microdomain composition. The reliance on indirect and perturbing techniques has led to vigorous debate concerning the nature and even existence of some microdomains. Recently, increasing technical sophistication has been applied to study cell surface compartmentalization providing evidence for small, short-lived clusters that may be much less than 50 nm in diameter. Lipid rafts and caveolae are cholesterol-dependent, highly ordered microdomains that have received most attention in recent years, yet their precise roles in regulating functions such as cell signalling remain to be determined. Endocytosis of lipid rafts/caveolae follows a clathrin-independent route to both early endosomes and non-classical caveosomes. The observation that a variety of cellular pathogens localize to and internalize with these microdomains provides an additional incentive to characterize the organization, dynamics and functions of these domains.     

Membrane receptors for oestrogen in the brain

Oestrogen is important for the development of neuroendocrine centres and other neural networks including limbic and motor systems. Later in adulthood, oestrogen regulates the functional performance of different neural systems and is presumably implicated in the modulation of cognitive efficiency. Although still a matter of controversial discussion, clinical and experimental studies point at a potential neuroprotective role of oestrogen. Concerning the concept of cellular oestrogen action, it is undisputed that it comprises the binding and activation of nuclear receptors. The last decades have, however, immensely broadened the spectrum of steroid signalling within a cell. Novel steroid-activated intracellular signalling mechanisms were described which are usually termed 'non-classical' or 'non-genomic'. The brain appears to be a rich source of this new mode of oestrogen action. Studies from the past years have pinpointed non-classical oestrogen effects in many CNS regions. All available data support the view that non-classical oestrogen action requires interactions with putative membrane binding sites/receptors. In this article, we aim at compiling the most recent findings on the nature and identity of membrane oestrogen receptors with respect to the brain. We also attempt to turn readers attention to the coupling of these 'novel' receptors to distinct intracellular signalling pathways.     

Sorting out Sox10 functions in neural crest development

For both vertebrate developmental and evolutionary biologists, and also for clinicians, the neural crest (NC) is a fundamental cell population. An understanding of Sox10 function in NC development is of particular significance since Sox10 mutations underlie several neurocristopathies. Surprisingly, experiments in different model organisms aimed at identifying Sox10's role(s) have suggested at least four distinct functions. Sox10 may be critical for formation of neural crest cells (NCCs), maintaining multipotency of crest cells, specification of derivative cell fates from these cells and their differentiation. Here, I discuss this controversy and argue that these functions are, in part, molecularly interrelated.     

A monoclonal antibody against synaptic AChE: a useful tool for detecting apoptotic cells

The classical function of acetylcholinesterase (AChE) is to terminate synaptic transmission at cholinergic synapses by rapidly hydrolyzing the neurotransmitter acetylcholine (ACh). Non-classical functions of AChE involve accelerating the assembly of Abeta peptide into amyloid fibrils and participating in haematopoiesis and neurite growth. Although numerous antibodies have been raised against AChE, many researchers have questioned their reliability to identify the AChE in situ, especially with the regard to its non-classical roles. Researchers attended the Ninth International Meeting on Cholinesterase raised this question by showing different Western blot patterns of AChE detected by different Abs. Producing more effective and reliable Abs for measuring AChE in vivo or in situ has become an important issue in many scientific fields. In this paper, we introduce a monoclonal antibody raised against synaptic AChE that we identified by Western blot assays, immunofluorescent staining and immunoprecipitation of AChE, and mass spectrometry. Our results strongly demonstrate the specificity of our monoclonal antibody to recognize synaptic AChE; hence our antibody can be used as an effective tool to study the various functions of AChE. Since the apoptosis-related AChE was its synaptic form, our antibody can be used as a tool to detect apoptotic cells.     

“Inflammatory” Cytokines

If cytokines are constitutively expressed by and act on neurons in normal adult brain, then we may have to modify our current view that they are predominantly inflammatory mediators. We critically reviewed the literature to determine whether we could find experimental basis for such a modification. We focused on two "proinflammatory" cytokines, interleukin (IL)-1 and tumor necrosis factor-alpha (TNFalpha) because they have been most thoroughly investigated in shaping our current thinking. Evidence, although equivocal, indicates that the genes coding for these cytokines and their accessory proteins are expressed by neurons, in addition to glial cells, in normal brain. Their expression is region- and cell type-specific. Furthermore, bioactive cytokines have been extracted from various regions of normal brain. The cytokines' receptors selectively are present on all neural cell types, rendering them responsive to cytokine signaling. Blocking their action modifies multiple neural "housekeeping" functions. For example, blocking IL-1 or TNFalpha by several independent means alters regulation of sleep. This indicates that these cytokines likely modulate in the brain behavior of a normal organism. In addition, these cytokines are likely involved in synaptic plasticity, neural transmission, and Ca2+ signaling. Thus, the evidence strongly suggests that these cytokines perform neural functions in normal brain. We therefore propose that they should be thought of as neuromodulators in addition to inflammatory mediators.     

Extracellular matrix and embryonal morphogenesis: role of fibronectin in cell migration

The neural crest provides a useful paradigm for cell migration and modulations in cell adhesion during morphogenesis. In the present review, we describe the major findings on the role of the extracellular matrix glycoprotein fibronectin and its corresponding integrin receptor in the locomotory behavior of neural crest cells. In vivo, fibronectin is associated with the migratory routes of neural crest cells and, in some cases, it disappears from the environment of the cells as they stop migrating. In vitro, neural crest cells show a great preference for fibronectin substrates as compared to other matrix molecules. Both in vivo and in vitro, neural crest cell migration can be specifically inhibited by antibodies or peptides that interfere with the binding of fibronectin to its integrin receptor. However, the migratory behavior of neural crest cells cannot result solely from the interaction with fibronectin. Thus, neural crest cells exhibit a particular organization of integrin receptors on their surface and develop a cytoskeletal network which differs from that of non-motile cells. These properties are supposed to permit rapid changes in the shape of cells and to favor a transient adhesion to the substratum. Recent findings have established that different forms of fibronectin may occur, which differ by short sequences along the molecule. The functions of most of these sequences are not known, except for 1 of them which carries a binding site for integrin receptors. We have demonstrated that this site is recognized by neural crest cells and plays a crucial role in their displacement. It is therefore possible that the forms of fibronectin carrying this sequence are not evenly distributed in the embryo, thus allowing migrating neural crest cells to orientate in the embryo. Fibronectin would then not only play a permissive role in embryonic cell motility, but have an instructive function in cell behavior.     

Co-opting functions of cholinesterases in neural, limb and stem cell development

Acetylcholinesterase (AChE) is a most remarkable protein, not only because it is one of the fastest enzymes in nature, but also since it appears in many molecular forms and is regulated by elaborate genetic networks. As revealed by sensitive histochemical procedures, AChE is expressed specifically in many tissues during development and in many mature organisms, as well as in healthy and diseased states. Therefore it is not surprising that there has been a long-standing search for additional, "non-classical" functions of cholinesterases (ChEs). In principle, AChE could either act nonenzymatically, e.g. exerting cell adhesive roles, or, alternatively, it could work within the frame of classic cholinergic systems, but in non-neural tissues. AChE might be considered a highly co-opting protein, since possibly it combines such various functions within one molecule. By presenting four different developmental cases, we here review i) the expression of ChEs in the neural tube and their close relation to cell proliferation and differentiation, ii) that AChE expression reflects a polycentric brain development, iii) the retina as a model for AChE functioning in neural network formation, and iv) nonneural ChEs in limb development and mature bones. Also, possible roles of AChE in neuritic growth and of cholinergic regulations in stem cells are briefly outlined.     

Functional idiotypic mimicry of an adhesion- and differentiation-promoting site on acetylcholinesterase

Acetylcholinesterase mediates cell adhesion and neurite outgrowth through a site associated with the peripheral anionic site (PAS). Monoclonal antibodies raised to this site block cell adhesion. We have raised anti-idiotypic antibodies to one of these antibodies. The anti-idiotypic antibodies recognized the immunogenic antibody and non-specific mouse IgG, but not acetylcholinesterase. Five antibodies (out of 143 clones, an incidence of 3.5%) were able to promote neurite outgrowth in human neuroblastoma cells in vitro in a similar manner to acetylcholinesterase itself, suggesting that these antibodies carry an internal image of the neuritogenic site. Two of the antibodies were significantly more effective (P < 0.01) than acetylcholinesterase in this regard. The antibodies also bound specifically to mouse laminin-1 and human collagen IV, as does acetylcholinesterase. This binding was displaced by unlabelled antibody, as well as by acetylcholinesterase itself, indicating competition with acetylcholinesterase. We have also investigated the development of anti-anti-idiotypic antibodies in mice in vivo, and have observed that four of these (out of 318 clones, an incidence of 1.26%) mimic the idiotypic antibody and abrogate adhesion in neuroblastoma cells. We have thus demonstrated functional mimicry of the neuritogenic site on acetylcholinesterase in anti-idiotypic antibodies, enhancement of this activity in one antibody, and mimicry of the idiotypic antibody site in anti-anti-idiotypic antibodies. Implications of these findings for differentiation-promoting cancer therapy are discussed.     

NTPDases in the neuroendocrine hypothalamus: Possible energy regulators of the positive gonadotrophin feedback

Background  

Brain-derived ectonucleoside triphosphate diphosphohydrolases (NTPDases) have been known as plasma membrane-incorporated enzymes with their ATP-hydrolyzing domain outside of the cell. As such, these enzymes are thought to regulate purinergic intercellular signaling by hydrolyzing ATP to ADP-AMP, thus regulating the availability of specific ligands for various P2X and P2Y purinergic receptors. The role of NTPDases in the central nervous system is little understood. The two major reasons are the insufficient knowledge of the precise localization of these enzymes in neural structures, and the lack of specific inhibitors for the various NTPDases. To fill these gaps, we recently studied the presence of neuron-specific NTPDase3 in the mitochondria of hypothalamic excitatory neurons by morphological and functional methods. Results from those studies suggested that intramitochondrial regulation of ATP levels may play a permissive role in the neural regulation of physiological functions by tuning the level of ATP-carried energy that is needed for neuronal functions, such as neurotransmission and/or intracellular signaling.     

Invertebrate acetylcholinesterases: Insights into their evolution and non-classical functions

Acetylcholinesterase (AChE) plays a pivotal role in synaptic transmission by hydrolyzing the neurotransmitter acetylcholine. In addition to the classical function of AChE in synaptic transmission, various non-classical functions have been elucidated. Unlike vertebrates possessing a single AChE gene (ace), invertebrates (nematodes, arachnids, and insects) have multiple ace loci, encoding diverse AChEs with a range of different functions. In the field of toxicology, AChE with synaptic function has long been exploited as the target of organophosphorus and cabarmate pesticides to control invertebrate pests for the past several decades. However, many aspects of the evolution and non-classical roles of invertebrate AChEs are still unclear. Although currently available information on invertebrate AChEs is fragmented, we reviewed the recent findings on their evolutionary status, molecular/biochemical properties, and deduced non-classical (non-neuronal) functions.     

CREB signalling in neural stem/progenitor cells: recent developments and the implications for brain tumour biology

This paper discusses the evidence for the role of CREB in neural stem/progenitor cell (NSPC) function and oncogenesis and how these functions may be important for the development and growth of brain tumours. The cyclic-AMP response element binding (CREB) protein has many roles in neurons, ranging from neuronal survival to higher order brain functions such as memory and drug addiction behaviours. Recent studies have revealed that CREB also has a role in NSPC survival, differentiation and proliferation. Recent work has shown that over-expression of CREB in transgenic animals can impart oncogenic properties on cells in various tissues and that aberrant CREB expression is associated with tumours in patients. It is the central position of CREB, downstream of key developmental and growth signalling pathways, which give CREB the ability to influence a spectrum of cell activities, such as cell survival, growth and differentiation in both normal and cancer cells.     

How are the Non-classically Secreted Bacterial Proteins Released into the Extracellular Milieu?

Most bacterial proteins that are destined to leave the cytoplasm are exported across the cell membrane to their sites of function. These proteins are generally exported via the classical secretion pathway, in which the signal peptide plays a central role. However, some bacterial proteins have been found in the extracellular milieu without any apparent signal peptide. As none of the classical secretion systems is involved in their secretion, this occurrence is termed non-classical protein secretion. The mechanism or mechanisms responsible for non-classical secretion are contentious. This review compiles evidence from the debate over whether the release of the non-classically secreted proteins is the result of cell lysis and discusses how these proteins are exported to the exterior of the cell.