Shapira MichaelThe Hebrew University of Jerusalem, Dept. of Biological Chemistry, Institute of Life Sciences, Jerusalem 91904 IsraelPhone : 972-2-658-5109 Fax : 972-2-652-0258
To study the regulation of acetylcholinesterase (AChE) gene expression in human brain tumors, 3' splice variants of AChE mRNA and potentially relevant transcription factor mRNAs were labeled in primary astrocytomas and melanomas. AChE-S and AChE-R mRNA, as well as Runx1/AML1 mRNA accumulated in astrocytomas in correlation with tumor aggressiveness, but neither HNF3beta nor c-fos mRNA was observed in melanoma and astrocytomas. Immunohistochemistry demonstrated nuclear Runx1/AML1 and cellular AChE-S and AChE-R in melanomas, however, only AChE-S, and not the secreted AChE-R variant, was retained in astrocyte tumor cells. Runx1/AML1 revealed weak linkage with ACHE promoter sequences, yet enhanced ACHE gene expression in co-transfected COS1 cells. The p300 co-activator and the ACHE promoter's distal enhancer facilitated this effect, which was independent of much of the Runx1/AML1 trans-activation domain. Surprisingly, GASP, a fusion product of green fluorescence protein (GFP) and ASP(67), a peptide composed of the 67 C-terminal amino acid residues of AChE-S, localized to COS1 cell nuclei. However, GARP, the corresponding fusion product of GFP with a peptide having the 51 C-terminal residues of AChE-E or GFP alone, remained cytoplasmic. Runx1/AML1 exhibited improved nuclear retention in GASP-expressing COS1 cells, suggesting modulated nuclear localization processes. Together, these findings reveal brain tumor-specific regulation of both expression and cellular retention of variant ACHE gene products.
Title: Genomic dissection reveals locus response to stress for mammalian acetylcholinesterase Grant AD, Shapira M, Soreq H Ref: Cellular Molecular Neurobiology, 21:783, 2001 : PubMed
The mammalian acetylcholinesterase (ACHE) locus was investigated using computational predictive methods and experiments of reverse transcription polymerase chain reaction (RT-PCR). Computational analysis identified two genes downstream to ACHE, an inversely oriented arsenite resistance gene homologue (ARS), and a novel previously unidentified gene (PIX), co-oriented with ACHE. Experimental evidence shows coregulation of murine ACHE and ARS following confined swim, indicating coordinated locus response to stress, that is possibly mediated by altered cholinergic neurotransmission.
Title: Changes in neuronal acetylcholinesterase gene expression and division of labor in honey bee colonies Shapira M, Thompson CK, Soreq H, Robinson GE Ref: Journal of Molecular Neuroscience, 17:1, 2001 : PubMed
Division of labor in honey bee colonies is highlighted by adult bees making a transition at 2-3 wk of age from working in the hive to foraging for nectar and pollen outside. This behavioral development involves acquisition of new tasks that may require advanced learning capabilities. Because acetylcholinesterase (AChE) hydrolyzes acetylcholine, a major neurotransmitter associated with learning in the insect brain, we searched for changes in AChE expression in the brain during bee behavioral development. Biochemical aspects of the AChE protein were similar in foragers and "nurse" bees that work in the hive tending brood. However, catalytic AChE activity was significantly lower in foragers. Cloning of bee AChE cDNA enabled mRNA analysis, which demonstrated that the forager-related decrease in AChE activity was associated with decreased AChE mRNA levels. This was particularly apparent in the mushroom bodies, a brain region known to be involved with olfactory and visual learning and memory. In addition, treatment with the AChE-inhibitor metrifonate improved performance in an olfactory-learning assay. These findings demonstrate long-term, naturally occurring developmental downregulation of AChE gene expression in the bee brain, and suggest that this genomic plasticity can contribute to facilitated learning capabilities in forager bees.
Title: Genomic and transcriptional characterization of the human ACHE locus: complex involvement with acquired and inherited diseases Shapira M, Grant A, Korner M, Soreq H Ref: Isr Med Assoc J, 2:470, 2000 : PubMed
BACKGROUND: Abnormal levels of the acetylcholinesterase enzyme or aberrations involving the long arm of chromosome 7, harboring the ACHE gene at 7q22, occur in various diseases such as Alzheimer's, Parkinson's, and leukemias. However, the cause(s) of these abnormalities are still unknown. OBJECTIVE: To search for the genomic elements and transcriptional processes controlling ACHE gene expression and the plausible stability of its locus, by isolating, sequencing and characterizing the human (h)ACHE locus and its mRNA products. METHODS: Three clones containing the ACHE gene were isolated from a human chromosome 7 cosmid library. Two of these clones were thereafter sequenced and searched for repetitive elements, open reading frames and corresponding expressed sequence tags. Reverse transcription-polymerase chain reaction was employed to further explore these findings. RESULTS: The locus harboring the G,C-rich ACHE gene was found to be exceptionally rich in Alu repeats. It includes an additional, inversely oriented gene (ARS), tentatively associated with arsenite resistance. EST clones corresponding to both genes were found in cDNA libraries from 11 different human tissue sources, with ARS expressed in 10 additional tissues. Co-regulation of brain ACHE and ARS was suggested from their mutually increased expression following acute psychological stress. CONCLUSIONS: The abundance of Alu retrotransposones may predispose the ACHE locus to chromosomal rearrangements. Additionally, coordinated transcriptional regulation is implied from the joint ARS-AChE expression in stress insult responses. Disease-related changes in AChE may therefore reflect locus-specific regulation mechanisms affecting multiple tissues.
Hypersensitivity to acetylcholinesterase inhibitors (anti-AChEs) causes severe nervous system symptoms under low dose exposure. In search of direct genetic origin(s) for this sensitivity, we studied six regions in the extended 22 kb promoter of the ACHE gene in individuals who presented adverse responses to anti-AChEs and in randomly chosen controls. Two contiguous mutations, a T-->A substitution, disrupting a putative glucocorticoid response element, and a 4-bp deletion, abolishing one of two adjacent HNF3 binding sites, were identified 17 kb upstream of the transcription start site. Allele frequencies for these mutations were 0.006 and 0.012, respectively, in 333 individuals of various ethnic origins, with a strong linkage between the deletion and the biochemically neutral H322N mutation in the coding region of ACHE. Heterozygous carriers of the deletion included a proband who presented with acute hypersensitivity to the anti-AChE pyridostigmine and another with unexplained excessive vomiting during a fourth pregnancy following three spontaneous abortions. Electromobility shift assays, transfection studies and measurements of AChE levels in immortalized lymphocytes as well as in peripheral blood from both carriers and non-carriers, revealed functional relevance for this mutation both in vitro and in vivo and showed it to increase AChE expression, probably by alleviating competition between the two hepatocyte nuclear factor 3 binding sites. Moreover, AChE-overexpressing transgenic mice, unlike normal FVB/N mice, displayed anti-AChE hypersensitivity and failed to transcriptionally induce AChE production following exposure to anti-AChEs. Our findings point to promoter polymorphism(s) in the ACHE gene as the dominant susceptibility factor(s) for adverse responses to exposure or to treatment with anti-AChEs.
The extended human acetylcholinesterase (AChE) promoter contains many binding sites for osteogenic factors, including 1,25-(OH)2 vitamin D3 and 17beta-estradiol. In differentiating osteosarcoma Saos-2 cells, both of these factors enhanced transcription of the AChE mRNA variant 3' terminated with exon 6 (E6-AChE mRNA), which encodes the catalytically and morphogenically active E6-AChE isoform. In contrast, antisense oligodeoxynucleotide suppression of E6-AChE mRNA expression increased Saos-2 proliferation in a dose- and sequence-dependent manner. The antisense mechanism of action was most likely mediated by mRNA destruction or translational arrest, as cytochemical staining revealed reduction in AChE gene expression. In vivo, we found that E6-AChE mRNA levels rose following midgestation in normally differentiating, postproliferative fetal chondrocytes but not in the osteogenically impaired chondrocytes of dwarf fetuses with thanatophoric dysplasia. Taken together, these findings suggest morphogenic involvement of E6-AChE in the proliferation-differentiation balance characteristic of human osteogenesis.
Title: In vivo and in vitro resistance to multiple anticholinesterases in Xenopus laevis tadpoles Shapira M, Seidman S, Livni N, Soreq H Ref: Toxicol Lett, 103:205, 1998 : PubMed
Natural and man-made anticholinesterases comprise a significant share of the Xenobiotic poisons to which many living organisms are exposed. To evaluate the potential correlation between the resistance of acetylcholinesterase (AChE) to such toxic agents and the systemic toxicity they confer, we characterized the sensitivity of AChE from Xenopus laevis tadpoles to inhibitors, examined the susceptibility of such tadpoles to poisoning by various anticholinesterases and tested the inhibitor sensitivities of recombinant human AChE produced in these amphibian embryos from microinjected DNA. Our findings reveal exceptionally high resistance of Xenopus AChE to carbamate, organophosphate and quaternary anticholinesterases. In spite of the effective in vivo penetrance to Xenopus tadpole tissues of paraoxon, the poisonous metabolite of the pro-insecticide parathion, the amphibian embryos displayed impressive resistance to this organophosphorous agent. The species specificity of this phenomenon was clearly displayed in Xenopus tadpoles expressing recombinant human AChE, which was far more sensitive than the frog enzyme to in vivo paraoxon inhibition. Our findings demonstrate a clear correlation between AChE susceptibility to enzymatic inhibition and the systemic toxicity of anticholinesterases and raise a serious concern regarding the use of Xenopus tadpoles for developmental toxicology tests of anticholinesterases.
Title: The Human Ache Locus Includes a Polymorphic Enhancer Domain 17KB Upstream from the Transcription Start Site Shapira M, Korner M, Bosgraaf L, Tur-Kaspa I, Soreq H Ref: In: Structure and Function of Cholinesterases and Related Proteins - Proceedings of Sixth International Meeting on Cholinesterases, (Doctor, B.P., Taylor, P., Quinn, D.M., Rotundo, R.L., Gentry, M.K. Eds) Plenum Publishing Corp.:111, 1998 : PubMed
Title: Genetic manipulations of cholinergic communication reveal trans-acting control mechanisms over acetylcholine receptors. Broide RS, Grifman M, Shapira M, Ginzberg D, Soreq H Ref: Journal of Receptor & Signal Transduction Research, 17:279, 1997 : PubMed
Several approaches have been developed for genetic modulations of receptor expression. These initiated with gene cloning and heterologous expression in microinjected Xenopus oocytes, and proceeded through transgenic expression and genomic disruption of receptor genes in mice. In addition, antisense treatments have reduced receptor levels in a transient, reversible manner. Integration of foreign DNA with host genomic sequences yields both cis- and trans-acting responses. These may depend on the DNA integration site, host cells condition and most importantly, the affected signal transduction circuit. For example, acetylcholinesterase (AChE) overexpression in microinjected Xenopus tadpoles has been shown to upregulate alpha-bungarotoxin binding levels, indicating trans-acting control conferring overproduction of muscle nicotinic acetylcholine receptors. In transgenic mice expressing human AChE, the hypothermic response to oxotremorine was suppressed, reflecting modified levels of brain muscarinic receptors. To dissociate the feedback processes occurring in transfected cells from responses related to DNA integration, we examined the endogenous expression of the alpha 7 neuronal nicotinic acetylcholine receptor in PC12 cells transfected with DNA vectors carrying alternative splicing variants of human AChE mRNA. Our findings demonstrate suppression of alpha 7 receptor levels associated with the accumulation of foreign DNA in the transfected cells. Acetylcholine receptor levels thus depend on multiple elements, each of which should be considered when genetic interventions are employed.
Title: Alternative Exon 6 Directs Synaptic Localization of Recombinant Human Acetylcholinesterase in Neuromuscular Junctions of Xenopus laevis Embryos Sternfeld M, Seidman S, Ben Aziz-Aloya R, Shapira M, Timberg R, Kaufer D, Soreq H Ref: In Enzyme of the Cholinesterase Family - Proceedings of Fifth International Meeting on Cholinesterases, (Quinn, D.M., Balasubramanian, A.S., Doctor, B.P., Taylor, P., Eds) Plenum Publishing Corp.:45, 1995 : PubMed
Title: Transgenic engineering of neuromuscular junctions in Xenopus laevis embryos transiently overexpressing key cholinergic proteins Shapira M, Seidman S, Sternfeld M, Timberg R, Kaufer D, Patrick J, Soreq H Ref: Proceedings of the National Academy of Sciences of the United States of America, 91:9072, 1994 : PubMed
To examine the role of key cholinergic proteins in the formation of neuromuscular junctions (NMJs), we expressed DNAs encoding the mouse muscle nicotinic acetylcholine receptor (nAChR) or human brain and muscle acetylcholinesterase (hAChE) in developing Xenopus laevis embryos. Acetylthiocholine hydrolysis and alpha-bungarotoxin binding in homogenates of transgenic embryos revealed transient overexpression of the respective proteins for at least 4 days postfertilization. Moreover, hAChE injection induced an approximately 2-fold increase in endogenous Xenopus nAChR. Electron microscopy coupled with cytochemical staining for AChE activity revealed that AChE-stained areas, which reached 0.17 microns2 in NMJs of control embryos raised at 21 degrees C, increased up to 0.53 and 0.60 microns2 in nAChR and hAChE transgenics, respectively. These increases coincided with the appearance of a class of large NMJs with average postsynaptic lengths up to 1.8-fold greater than controls. As much as 57% and 34% of the NMJs in animals transgenic for nAChR and hAChE, respectively, displayed AChE activity in nerve terminals in addition to muscle labeling, as compared with 10% nerve-labeled NMJs in control animals. Moreover, area, but not length values, were > 2-fold larger in hAChE-expressing NMJs labeled in their nerve terminals than in those labeled in muscle alone, reflecting a hAChE-induced increase in synaptic cleft width. These findings indicate that modulation of cholinergic neurotransmission in NMJs modifies the features of nerve-muscle connections.
