Ben Aziz-Aloya R et al. (1993), Expression of a human acetylcholinesterase prom...

XB-ART-22740

Proc Natl Acad Sci U S A 1993 Mar 15;906:2471-5.

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Expression of a human acetylcholinesterase promoter-reporter construct in developing neuromuscular junctions of Xenopus embryos.

Ben Aziz-Aloya R , Seidman S , Timberg R , Sternfeld M , Zakut H , Soreq H .

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We have employed Xenopus embryos to express human acetylcholinesterase (AcChoEase; EC 3.1.1.7) in developing synapses. Transcription of AcChoEase mRNA was driven by a 2.2-kb sequence upstream from the initiator AUG in the ACHE gene encoding AcChoEase, with multiple potential sites for binding universal and tissue-specific transcription factors. These included clustered MyoD elements, E-box, SP1, EGR1, AP-2, and the development-related GAGA motif. A DNA construct composed of this sequence linked to a 2.1-kb sequence encoding human AcChoEase was designated human AcChoEase promoter-reporter (HpACHE). HpACHE but none of its several 5'-truncated derivatives was transcriptionally active in developing Xenopus embryos. Furthermore, PCR analysis using chimeric PCR primers revealed usage of the same 1.5-kb intron and 74-bp exon within the HpACHE sequence in microinjected embryos and various human tissues. Cytochemical staining revealed conspicuous accumulation of overexpressed AcChoEase in neuromuscular junctions and within muscle fibers of apparently normal 2-day Xenopus embryos injected with HpACHE. The same reporter driven by the cytomegalovirus promoter was similarly efficient in directing the heterologous human enzyme toward neuromuscular junctions, attributing the evolutionary conservation of AcChoEase targeting to the coding sequence. Our findings demonstrate that a short DNA sequence is sufficient to promote the exogenous transcription and faithful splicing of human AcChoEase mRNA in developing Xenopus embryos and foreshadow their use for integrative studies of cholinergic signaling and synapse formation.

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Species referenced: Xenopus laevis
Genes referenced: ache creb1 egr1 myod1 sp1 tfap2a

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	FIG. 1. ACHE 5' upstream sequence. DNA sequencing was performed as detailed (8) on single- and double-stranded DNA by using commercial (Stratagene) or unique primers determined by sequencing. Data analysis (N-SITES program, University of Wisconsin) revealed potential binding sites for several transcription factors, including MyoD (nt 37,91, 129, 226, 234,348, 1332, and 2130; boxed), Spl (nt 515, 521, 534, 540, 544, 699, 805, 994, 1246, 1358, 1481, and 1762, circled), and additional sites (underlined): ATF/CREB (nt 67), E-box (nt 89), Zeste (nt 213 and 855), AP-2 (nt 443 and 1444), GAGA (nt 477), EGR1 (nt 517, 536, and 546), NF-KB (nt 705 and 1372), CCAAT box (nt 990 and 1666), and the TATA box (nt 1176). Arrows indicate potential sites for splicing at the 5' acceptor site (G/GT). The consensus splicing motif (CAG/A) required at the 3' boundaries of introns is noted by an arrowhead. One of several putative cap sites is noted by a [ sign. PL /, polylinker including a Sac I site.
	FIG. 2. Transcription of HpACHE in Xenopus. (Upper) Injected HpACHE DNAs included the 2.2-kb AcChoEase upstream sequence or its deletion constructs linked to the AcChoEase coding sequence. Characteristic restriction sites (S, Sac I; X, Xho I; A, Acc I; K, Kpn I; P, Pvu II; SP, Sph I; St, Stu I) included in the AcChoEase coding exons (exons 2, 3, 4, and 6, shaded boxes) and in the region upstream of the initiator AUG codon within clone GNACHE (8) were predicted according to sequence data and confirmed by blot hybridization of genomic DNA with PCR-amplified or subcloned probes from this sequence. Relative positions are noted on the length scale in kb, where the first sequenced nucleotide is numbered zero. A fifth construct, carrying the AcChoEase coding sequence downstream of the cytomegalovirus immediate early gene enhancer-promoter sequence (solid box), was as described (17). Putative TATA box and cluster of transcription factor binding sites (Fig. 1) are marked by a solid box and an asterisk, respectively. Open reading frames in exons are noted by dotted underlines. Positions of the first exon (exon 1) and intron (intron I1) were determined by RNA-PCR experiments (Fig. 3). (Lower) RNA was extracted from Xenopus oocytes 2 days after injection (50 ng per oocyte) with the noted linearized constructs. Residual injected DNA was eliminated by DNase I treatment [20 min at 37°C, 2 units per sample (Promega)] in 40 mM Tris.HCl/10 mM NaCl/6 mM MgCl2 in the presence of RNasin (Boehringer Mannheim; 20 units per sample). DNase I was heat-inactivated (90°C, 8 min) and RNA-PCR amplification was performed using the primer pair 11/12. Lanes: U, uninjected; P, X, K, and S, constructs (named after the restriction enzymes used to prepare them) (Upper); C, CMVACHE; M, DNA size marker VI (Boehringer Mannheim). PCR products are indicated by the arrows.
	FIG. 3. RNA-PCR analysis of exon-intron boundaries. (Upper) Potential 5' splice sites (consensus G/GT) were found in the AcCho- Ease upstream region at the noted positions in the sequence presented in Fig. 1. A potential 3' splice site was known to be located at position 2226, 21 nt upstream from the first AUG (8). Chimeric downstream-oriented (+) PCR primers were computer-designed (20) to function only if their entire consecutive sequence would be present-i.e., wherever splicing occurred. These included 15-21 nt upstream from each potential 5' splice site and an additional 5 or 6 nt from exon 2 (ACGCCG, nt 2227-2232) and were tested with a single upstream (-) primer (primer 10). The asterisk indicates the experimentally confirmed active 5' splice site. (Lower Right) Total RNA was extracted from adult human (70 years old) brain basal nuclei. RNA-PCRs with the chimeric primer 2 and standard PCR primers 6-8 resulted in PCR products with increasing lengths (lanes 2 and 6-8). An additional primer at position 590 remained inactive (data not shown), delineating 74 bp for El. Lane M contains molecular size markers (Boehringer Mannheim). Lanes 1 and 3-5 contain brain RNA and chimeric primers 1 and 3-5, which remained inactive when paired with primer 10. (Lower Left) RNA extracted from Xenopus oocytes (lanes XO) and 2-day embryos (lanes XE) injected with the HpACHE (lanes S) construct (Fig. 2) was used for RNA-PCR experiments using primers 2 and 10. Lane U, uninjected.
	FIG. 4. AcChoEase expression in developing Xenopus embryos. (A) Schematic presentation of sectioned embryos. Thin sections (700 A) were prepared from the anterior trunk region (Upper) of 2-day embryos. Cross sections (Lower) at this level reveal the close proximity of the muscle-forming myotomes and the principal components of the developing central nervous system. At this stage embryos displayed clearly differentiated muscle cells and the sporadic twitching that accompanies hatching. After cytochemical staining for catalytically active AcChoEase, electron microscopy was employed to detect high-density accumulations of thiocholine reaction product in myotome areas (shaded). (Diagrams are after ref. 21.) (Bar = 200 ,um.) (B) Accumulation of AcChoEase in myotomes of transgenic Xenopus embryos. Two-cell cleaving embryos of Xenopus laevis microinjected with 1 ng of plasmid DNA were cultured for 2 days. Shortly after hatching [stage 26 (21)], embryos were fixed and stained for catalytically active AcChoEase by the thiocholine hydrolysis method (14, 15). Deposits of electron-dense reaction product appear as dark rectangular crystals that vary in size and intensity (arrows). Control sections incubated in reaction buffer lacking substrate displayed no reaction product. Panels a-c show neuromuscular junctions (nmj) demonstrating uncharacteristic synaptic accumulation of AcChoEase after microinjection of HpACHE (panel b) and CMVACHE (panel c) DNAs. Panels: a, uninjected; b, HpACHE injected; c, CMVACHE injected. Sections through somitic muscle cells from control uninjected embryos (panel d) or HpACHE-injected (panel e) or CMVACHE-injected (panel f) embryos illustrating overexpression of AcChoEase around and between the myofibrils (mf) of both DNA-injected groups. Arrows denote crystals of reaction product. sv, Synaptic vesicles; y, yolk platelets. (Bar = 1 ,um.)

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