Correspondence to Joshua R. Sanes: sanesj{at}mcb.harvard.edu
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S.J. Eglen's present address is Dept. of Applied Mathematics and Theoretical Physics, University of Cambridge, Cambridge CB3 0WA, UK.
J.R. Sanes' present address is Dept. of Molecular and Cellular Biology, Harvard University, Cambridge, MA 02138.
Abbreviations used in this paper: AChE; acetylcholinesterase; AChR, acetylcholine receptor; GAPDH, glyceraldehyde-3-phosphate dehydrogenase; MuSK, muscle specific kinase; NMJ, neuromuscular junction; PH, pleckstrin homology; PI3K, phosphatidylinositol 3-kinase; PKARI
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Introduction |
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A key advance in addressing these issues was the discovery that some postsynaptic proteins are synthesized locally rather than (or in addition to) being synthesized at a distant site and then transported to the synapse. In forebrain neurons, for example, most protein synthesis occurs in the cell body but specific subsets of mRNAs are transported to dendritic spines, where they are translated (Steward, 1983; for reviews see Steward and Schuman, 2001; Martin and Kosik, 2002). Likewise, at the skeletal neuromuscular junction (NMJ), RNAs encoding some postsynaptic proteins are concentrated and translated directly beneath the postsynaptic membrane (Merlie and Sanes, 1985; Goldman and Staple, 1989; Jasmin et al., 1993, Moscoso et al., 1995b; Valenzuela et al., 1995; Imaizumi-Scherrer et al., 1996; for reviews see Sanes and Lichtman, 1999, 2001; Chakkalakal and Jasmin, 2003). The mechanism that underlies localized protein synthesis at the NMJ differs from that in neurons: RNA localization in muscle results, at least in part, from transcriptional specialization of the few myonuclei within the multinucleated muscle fiber that lie beneath the postsynaptic membrane (Klarsfeld et al., 1991; Sanes et al., 1991; Simon et al., 1992; for review see Schaeffer et al., 2001). The outcome is similar in neurons and muscles, however, in that specific mRNAs are localized to the postsynaptic apparatus.
Identification of these synaptic RNAs provides a means of identifying proteins likely to be important for synapse formation or function. Moreover, determining which synaptic components are synthesized locally is an important step in understanding how synapse assembly is regulated. In the first part of this paper, we report results of an expression-profiling screen designed to identify synaptically enriched RNAs in muscle. We used the elegant methods of Tietjen et al. (2003) to amplify RNAs from microdissected NMJs and to compare them to RNAs from synapse-free portions of muscle. This comparison led to identification of several new synaptic transcripts, encoding membrane, cytoplasmic, cytoskeletal, and nuclear proteins.
In the second part of the paper, we describe LL5ß, a protein encoded by one of the synaptic RNAs we identified. LL5ß was previously identified in a database search for proteins containing pleckstrin homology (PH) domains, which bind phosphoinositides on the inner leaflet of the plasma membrane (Dowler et al., 2000). Subsequent analysis showed that this binding is regulated by extracellular signals and that LL5ß also binds a cytoskeletal, actin-associated protein, filamin (Paranavitane et al., 2003), one form of which is concentrated at the NMJ (Bloch and Hall, 1983; Shadiack and Nitkin, 1991). We show here that LL5ß is associated with the postsynaptic membrane at the NMJ, that it is concentrated at borders of the postsynaptic domain as it develops, and that it regulates acetylcholine receptor (AChR) aggregation in this domain. We propose that LL5ß is a regulated link in a multimolecular complex that corrals AChRs in the postsynaptic apparatus.
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Results |
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Second, we used the amplification method of Tietjen et al. (2003) to prepare targets for hybridization to microarrays. After amplification, sample quality was assessed by Southern blotting for four transcripts known to be enriched in synaptic areas (the AChR -subunit, acetylcholinesterase [AChE], the protein kinase A RI
subunit [PKARI
], and the muscle specific kinase [MuSK]; references in Introduction), as well as two broadly expressed genes (glyceraldehyde-3-phosphate dehydrogenase [GAPDH] and cyclophilin). Pairs of samples were selected in which: (a) the synaptic sample was rich in products amplified from the synaptic genes, (b) the nonsynaptic sample contained little or none of these products, and (c) both samples had nearly equivalent levels of the broadly expressed genes (Fig. 1 E). Of >100 pairs analyzed, the nine that best fulfilled these criteria were hybridized to Affymetrix Murine U74A, B, and C GeneChips, which together contain 36,701 probe sets.
As a first test of the method, we calculated the synaptic enrichment of the six transcripts for which there was the best prior evidence of synaptic enrichment. Four of these (AChR, AChE, PKARI
, and MuSK) had been used for prescreening by Southern analysis, but the other two (AChR
and AChR
) had not. Enrichment of each transcript was calculated as the ratio of the synaptic to extrasynaptic expression levels (Table S1, available at http://www.jcb.org/cgi/content/full/jcb.200411012/DC1) and as the rank order of the synaptic/nonsynaptic ratios (Table I). All but 1 of the 54 ratios (6 genes x 9 pairs) were >1 (normalization set the mean ratio equal to 1), and all but the corresponding one rank order were above the mean of 18,350 (36,701/2). Both distributions were highly nonrandom (P < 1014; binomial test). Moreover, the geometric mean of ratios of these six control genes and the arithmetic mean of their rank order (Table S1 and Table I, bottom row) were much higher than expected by chance (P < 0.03 for pair No. 3 and P < 0.0006 for all other pairs; computed using bootstrapping tests). Ratios and rank orders for the transcripts that had been used for prescreening were not better than those that had not.
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The availability of multiple chip pairs and validated control transcripts afforded the opportunity to ask how many replicates are needed to obtain reliable rank orders. To this end, we calculated the mean rank order for the six control transcripts from each combination of the 36 (9 x 8/2) possible set of two pairs, each of the 84 (9 x 8 x 7/3 x 2) possible sets of three pairs, and so on. Results are shown in Fig. 2. The two lines enveloping the individual points show the best and worst rank orders that could be obtained; the central line shows the mean rank order (Fig. 2). Three features of the graph are noteworthy. First, as expected, the overall reliability of the rankings increases with the number of replicates (Fig. 2, middle line). Second, even though all pairs provide useful data, there is such great variability among them that the reliability of rankings varies manyfold depending on which particular pairs are considered (Fig. 2, difference between top and bottom lines). Third, if one can prospectively identify control genes, it is possible to obtain more reliable data from a subset of the pairs than from all of them (Fig. 2, bottom line). For example, the mean rank order of the six control genes is 19 for all nine pairs, but 14 for the best six pairs.
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Known synaptically-enriched proteins, n = 1.
Nestin, an intermediate filament protein originally identified in stem cells, is concentrated at the NMJ (Carlsson et al., 1999; Vaittinen et al., 1999). We find that its RNA is also enriched at synaptic sites.
Genes expressed by Schwann cells, n = 3.
Motor nerve terminals are ensheathed by Schwann cells, the glia of the peripheral nervous system. Therefore, synapse-rich samples used for expression profiling contained Schwann cells, whereas extrasynaptic samples, isolated from nerve-free regions, were Schwann cell-free. Therefore, we expected that genes expressed by Schwann cells would be enriched in the synaptic samples. Consistent with this expectation, three genes known to be selectively expressed by Schwann cells were within the top 25 transcripts: the transcriptional regulators PEA-3 and SOX-10 and the myelin protein zero (Jessen and Mirsky, 2002).
False positives, n = 5.
We obtained no evidence that transcripts expressed by five of the probe sets (Table II, Nos. 4, 7, 15, 17, and 25) were enriched at synaptic sites.
Novel transcripts enriched in synaptic regions, n = 10.
Quantitative RT-PCR and/or in situ hybridization confirmed synaptic enrichment of 10 gene products that had not previously been localized to the NMJ. As noted above, these transcripts might be expressed by muscle fibers, Schwann cells, or perhaps other synapse-associated cells (e.g., a specialized perisynaptic population of fibroblasts; Gatchalian et al., 1989). For five of the mRNAs, in situ hybridization signals were too weak or diffuse to allow distinction among these sites (Table II, Nos. 3, 8, 9, 20, and 24). For the other five, however, in situ hybridization revealed a punctate pattern of expression associated with individual muscle fibers (Fig. 3, A and B); this finding was most consistent with localization in the postsynaptic apparatus (Moscoso et al., 1995a, b), although association with Schwann cells cannot be ruled out. One of these gene products, LL5ß (No. 16; Fig. 3 B), is described in detail below (see Figs. 46). The other four are described in the following paragraphs.
The first gene product, CD24 (No. 6), is a small, highly glycosylated, membrane-associated protein. It has been studied most intensively in the immune system but is also expressed in the nervous system, where it has been implicated in the control of neurogenesis and neurite outgrowth (Calaora et al., 1996; Shewan et al., 1996; Kleene et al., 2001; Belvindrah et al., 2002).
The second gene product, Unc53H3/neuron navigator 3/ POMFIL1 (No. 11; Coy et al., 2002; Maes et al., 2002; Merrill et al., 2002), is predicted, on the basis of its sequence, to be a cytoplasmic, actin-binding adaptor protein. It is one of three mammalian orthologues of Caenorhabditis elegans unc-53. Unc 53 mutants exhibit defects in axon branching and muscle formation (Hekimi and Kershaw, 1993; Stringham et al., 2002), and unc53H2-deficient mice show defects in sensory acuity and optic nerve growth (Peeters et al., 2004).
The third gene product, ERM (No. 13), is a member of a large family of "Ets-domain" transcriptional regulators (Sharrocks, 2001). Ets-domain proteins are believed to promote selective transcription of AChR subunit genes by synaptic nuclei (Schaeffer et al., 2001). Attention has centered on the Ets-related proteins GABP- and -ß, but both RNAs are present in extrasynaptic as well as synaptic regions (Fromm and Burden, 1998; Schaeffer et al., 1998), suggesting that additional factors are involved in limiting GABP-mediated transcription to specific sites. That Ets-domain factors function as heterodimers makes it tempting to speculate that ERM plays such a role. Consistent with this possibility, Hippenmeyer et al. (2002) recently published micrographs suggesting selective localization of ERM RNA in synaptic regions of embryonic muscle.
Finally, NTA (No. 18) RNA encodes a 217amino acid protein conserved in several mammalian species (mouse, rat, and human; UniGene identifiers are Mm 21836, Rn. 13571, and Hs. 157779, respectively). This RNA begins just 200 bp 3' to the last known exon of the AChE gene (Wilson et al., 2001), so we have given its locus the working name "NTA" for "next to AChE." It is unclear whether it represents an alternative transcriptional product of the AChE locus or a distinct gene. Our data are consistent with both possibilities: Northern analysis using an NTA-specific probe revealed transcripts of 1.2 and 3.8 kb in muscle, the former excluding and the latter including AChE-derived sequences (unpublished data). The differential regulation of NTA and AChE RNAs by innervation (see the following section) also implies the existence of distinct mRNAs.
In summary, of the top 25 genes from our microarray analysis, the synaptic enrichment of 20 was validated by a second method (RT-PCR, in situ hybridization, or published immunohistochemical localization). Of these 20, at least five encode RNAs that are concentrated very near the NMJ but have not previously been studied in the context of the NMJ. Remarkably, all five are plausible candidates for synaptic roles, based on their chromosomal localization (NTA), roles in other neural systems (Unc5h3 and CD24), known properties of synapse-specific transcription (ERM), or our own data (LL5ß; see Figs. 7 and 8).
The 25 probe sets that we analyzed gave signals that were >7.5-fold higher in synaptic than in extrasynaptic regions of muscle. Of the 36,701 probe sets queried, a total of 42, 70, 139, and 424 showed greater than six-, five-, four-, and threefold synaptic enrichment, respectively (Table S2, available at http://www.jcb.org/cgi/content/full/jcb.200411012/DC1). Almost surely, the incidence of false positives will increase as the enrichment decreases. Moreover, some of the true positives may encode proteins expressed by nonmuscle cells, such as Schwann cells or perisynaptic fibroblasts. Nonetheless, it seems likely that the list in Table S2 includes many additional novel synaptic components.
Coregulation of synaptically enriched transcripts
Several RNAs previously shown to be enriched at synaptic sitesnotably the AChR, ß, and
subunits, N-CAM, and MuSKshare two additional features: their abundance in muscle decreases as development proceeds and increases after denervation (Merlie et al., 1984; Covault et al., 1986; Goldman et al., 1988; Valenzuela et al., 1995). We asked whether or not RNAs encoding other components of the postsynaptic apparatus are regulated similarly.
First, we determined the synaptic enrichment of transcripts encoding basal lamina, plasma membrane, and cytoskeletal proteins concentrated in the postsynaptic apparatus (Peters et al., 1994; Miner and Sanes, 1994; Altiok et al., 1995; Moscoso et al., 1995a, b; Zhu et al., 1995; Patton et al., 1997; Sanes and Lichtman, 1999). In addition to those transcripts listed in Tables I and II, RNAs encoding AChRß, AChR, rapsyn, ColQ, erbB3, utrophin, N-CAM, laminins
5, and collagen
3(IV) were enriched in the synaptic samples (Table III). In contrast, RNAs encoding the basal lamina protein laminin ß2, the membrane protein erbB4, and the cytoskeletal protein syntrophin ß2 were not appreciably enriched in synaptic mRNA (unpublished data), even though their protein products are concentrated at synaptic sites.
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Synaptic genes are not, however, completely coregulated. Some variations from the common pattern have been noted previously, for example the postnatal up-regulation of AChR, and the down-regulation of AChE after denervation (Sanes and Lichtman, 1999). Another pattern is that of ERM RNA, which changes little during development or after denervation. Synaptic nuclei acquire specialized properties during development and maintain them in denervated muscle. Although AChR subunit genes are selectively transcribed by these nuclei, they are also transcribed by extrasynaptic nuclei during development and after denervation. Expression of a gene involved in controlling synapse-specific transcription might be expected to remain more confined to synaptic nuclei than expression of the genes it regulates. Our results are consistent with the idea that ERM is one such gene.
Synaptic localization of LL5ß
The rationale for our screen was that RNAs concentrated in synaptic areas encode proteins concentrated at synaptic sites. This idea was plausible but unproven, in that all synaptically enriched RNAs described to date were identified because their protein products were already known to be synaptic components. Therefore, we asked whether or not a novel gene identified in our screen, LL5ß, encoded a synaptic component.
LL5ß is an 160-kD protein containing two predicted coiled-coil domains, a serine-rich region predicted to contain multiple protein kinase C phosphorylation sites, and a phosphoinositide-binding module called a PH domain. Many PH domains selectively bind 3-phosphorylated phosphoinositides that are generated in the inner leaflet of the plasma membrane by phosphatidylinositol 3-kinase (PI3K); therefore, they serve to recruit signaling proteins to the membrane in response to PI3K activation (Lemmon and Ferguson, 2000). Paranavitane et al. (2003) showed that LL5ß binds both phosphatidylinositol (3,4,5)-triphosphate and a cytoskeletal adaptor protein,
-filamin, and that activation of PI3K regulates its association with the membrane. Two partial homologues of LL5ß are present in the mouse genome: LL5
, which binds phosphoinositides (Dowler et al., 2000) but has not been studied further, and a novel sequence that we found by database searching and call LL5
. The three members of the LL5 family all have two coiled-coiled domains and a PH domain, but strong homology is restricted to their carboxy termini; their amino termini are divergent in both sequence and domain structure (Fig. 4 A). To date, no physiological role has been reported for any member of the LL5ß family.
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These results demonstrate an association of LL5ß with the postsynaptic membrane of the NMJ. To ask if the PH domain mediates this association, we fused GFP to LL5ß or to a mutant LL5ß from which the PH domain had been deleted (LL5ßPH). Expression plasmids encoding GFP-LL5ß, GFP-LL5ß
PH, or GFP alone were electroporated into mouse anterior tibialis muscles. By 4 d after electroporation, GFP was colocalized with AChRs in muscle fibers expressing GFP-LL5ß (Fig. 5 A; n = 10). In contrast, GFP immunofluorescence was diffuse and cytoplasmic in fibers from muscles that had been transfected with GFP-LL5ß
PH or GFP alone (Fig. 5, B and C; n = 10 each). Likewise, GFP-LL5ß but not GFP-LL5ß
PH localized to AChR-rich clusters in cultured myotubes (unpublished data). Thus, its PH domain is essential for targeting LL5ß to the NMJ. In contrast, fusion of GFP to isolated PH domains did not localize to AChR clusters in myotubes (unpublished data), indicating that although the PH domain is necessary for localization it is not sufficient.
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LL5ß was associated with AChR-rich plaques in this system throughout their evolution, but its distribution differed systematically from that of AChRs. In simple plaques, AChRs were uniformly distributed, whereas LL5ß was concentrated around the circumference (Fig. 6 A). Subsequently, as plaques became perforated at their centers, the peripheral distribution of LL5ß became more marked (Fig. 6 B). In some cases, LL5ß also rimmed the outer circumference of the perforations that transform plaques into annuli and then into branched structures (Fig. 6, C and D). The tendency of LL5ß to concentrate at the periphery persisted in branched aggregates but was less striking (Fig. 6 E). Within aggregates, LL5ß and AChRs were often distributed in complementary patterns (Fig. 6 F); the distribution of LL5ß is reminiscent of that of vinculin and dystrophin (Bloch and Pumplin, 1988; Dmytrenko et al., 1993). Likewise, LL5ß and AChRs appeared to have complementary distributions at developing NMJs in vivo (Fig. 6 G), as well as at adult NMJs (Fig. 4 E), although the more favorable geometry of myotube cultures made details of the localization more readily appreciated in vitro.
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As a second approach to assessing the function of LL5ß, we overexpressed GFP-LL5ß in myotubes. The fusion protein was associated with AChR aggregates when it was expressed at modest levels (unpublished data; levels assessed by staining with anti-LL5ß, and comparing to endogenous levels in controls). In contrast, GFP-LL5ß was diffusely distributed in myotubes that expressed high levels of fusion protein, and few AChR aggregates were present in these myotubes (Fig. 8 A). Instead, AChRs in these myotubes were distributed diffusely and in small patches (Fig. 8 A). No perturbations were observed in myotubes expressing GFP alone, the GFP-LL5ßPH fusion protein, or the GFP-PH fusions (Fig. 8, BD; and not depicted), indicating that the effects of the LL5ß were specific. However, lacking another PH domaincontaining protein that localizes to AChR clusters, we cannot rule out the possibility that the effects of overexpression result from a nonphysiological perturbation of the AChR-rich domain.
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Discussion |
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Our analysis demonstrates the power of the Tietjen et al. (2003) method for expression profiling of tiny samples and provides some guidelines for its use. In particular, our data directly demonstrate that the amplification method generates high amplitude noise, which obscures enrichment of transcripts. In fact, most exceptionally high and low values obtained from any single GeneChip represent noise. Because this noise is more or less random, however, it is efficiently diluted when data sets are pooled, facilitating detection of genes that are consistently enriched, even if the degree of enrichment is modest.
We also used conventional expression profiling to show that greater than three fourths of the known and novel synaptic RNAs are coregulated during development and after denervation, suggesting the existence of a common regulatory program. One cis-element critical for synaptic expression is the N-box, a site that binds Ets-domain transcription factors; such sites are already known to play roles in the synaptic transcription of genes encoding AChR subunits, AChE, and utrophin (Koike et al., 1995; Schaeffer et al., 2001). Cis-elements called E-boxes, which bind basic helix-loop-helix factors, have been implicated in down-regulation during development and up-regulation after denervation. Many genes selectively transcribed in synaptic nuclei may share a set of such cis-elements, as envisioned for members of "synexpression groups" (Niehrs and Pollet, 1999). However, synaptic genes are not completely coregulated. Reasons for the exceptions are unknown, but we speculate that expression of genes involved in regulating synapse-specific transcription might be more confined to synaptic nuclei during development and after denervation than expression of the genes they regulate. ERM may be one such gene.
All five of the novel RNAs that we showed to be enriched at or near synaptic sites by in situ hybridization (NTA, Unc5h3, CD24, ERM, and LL5ß) are reasonable candidates for synaptic roles. Here, we focused exclusively on one of them, LL5ß. LL5ß had previously been shown to bind phosphoinositides and filamin (Dowler et al., 2000; Paranavitane et al., 2003), but its localization and physiological function were unknown. We found that LL5ß is a component of the postsynaptic apparatus, thereby validating our overall strategy. Moreover, detailed analysis of localization as well as loss- and gain-of-function analyses showed that LL5ß is part of the machinery required for aggregation of AChRs.
The mechanism by which LL5ß affects AChR aggregation remains to be explored, but some clues exist: (a) LL5ß is most highly concentrated in AChR-poor regions directly adjacent to AChR-rich regions (edges of clusters and interstices between microaggregates, in vitro and in vivo: Fig. 4 E; and Fig. 6, F and G). (b) Its association with the postsynaptic membrane is mediated by its phosphoinositide-binding PH domain (Fig. 5). (c) It binds to a cytoskeletal component, filamin (Paranavitane et al., 2003), one form of which is itself colocalized with clustered AChRs in myotubes (Bloch and Hall, 1983; Shadiack and Nitkin, 1991). (d) It can reorganize the cytoskeleton in response to extracellular signals that regulate its association with the membrane (Paranavitane et al., 2003). (e) AChR-rich and -poor regions within AChR aggregates differ in their lipid composition (Pumplin and Bloch, 1983; Scher and Bloch, 1991; Barrantes, 2002). Together, these data suggest a model in which LL5ß "corrals" AChRs by forming a dynamic link between specific lipids and the AChR-associated cytoskeleton; the link would remodel as AChR clusters grow or change in shape, and might even help direct shape changes.
In this model, corrals would be unable to form when LL5ß is absent, impeding clustering, whereas overexpression of LL5ß might inhibit AChR aggregation by preventing microaggregates from coalescing into larger clusters. Alternatively, when LL5ß is present in excess, some molecules might bind the cytoskeleton and others the membrane, disrupting the corraling complex and leading to a phenotype similar to that seen when LL5ß levels are decreased. The latter explanation is similar to that postulated for rapsyn, another protein associated with the cytoplasmic face of the postsynaptic membrane: no AChR clusters form in the absence of rapsyn (Gautam et al., 1995), but overexpression also inhibits clustering (Yoshihara and Hall, 1993; Han et al., 1999). One way to elucidate LL5ß's mechanism of action will be to identify the signals that affect its localization or binding capacity and to ask if it interacts with intracellular pathways already implicated in AChR clustering (Jones and Werle, 2000; Weston et al., 2000; Luo et al., 2002, 2003; Finn et al., 2003).
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Materials and methods |
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For analysis of gene regulation, we compared lower leg muscles from day 15 embryos, lower leg muscles from adults 4 d after unilateral section of the sciatic nerve, and contralateral innervated muscles from the same mice. Total RNA was isolated with Trizol Reagent (Invitrogen) and RNeasy Mini Kit (QIAGEN). RNA was converted to double-stranded cDNA with an oligo(dT) primer containing a T7 promotor and used for synthesis of biotinylated cRNA using a Bioarray HighYield Kit (Enzo). The cRNA targets were fragmentated as described previously (Lipshutz et al., 1999), and then hybridized to GeneChips as described for cDNA. Results from duplicate samples were averaged.
Data were analyzed with Affymetrix Microarray Suite 5.0 software package. The numerical signal intensity for each probe set was used for further calculation in Microsoft Excel and R (www.r-project.org). The SAM program (Tusher et al., 2001) was used at the threshold value of 0.05.
Quantitative RT-PCR
Mouse diaphragms were stained with rBTX as in Microarray analysis and divided into synapse-rich and -free segments (Merlie and Sanes, 1985). Total RNA was extracted, and 1-µg aliquots were used for cDNA synthesis. Products were used for quantitative RT-PCR using the TaqMan 7700 Sequence Detection System (PerkinElmer) and SYBER-GREEN dye (Applied Biosystems) as described previously (Wittwer et al., 1997; Morrison et al., 1998). Levels of GAPDH RNA were used for normalization. Assays were repeated on two independently prepared samples, and each sample was assayed in duplicate.
Antibody production
A fragment of LL5ß corresponding to aa 418760 was fused to a polyhistidine epitope tag, expressed in Escherichia coli, purified with Ni-NTA Spin Kit (QIAGEN), and used to immunize BalbC mice. Hybridomas were produced by standard methods, and their products were assayed by ELISA, using immobilized immunogen, and by immunostaining of COS cells transfected with a GFP-LL5ß fusion. Three mAbs (1H12, 6B9, and 7E3) were subcloned.
Evidence that these antibodies specifically recognize LL5ß is as follows: (a) the antibodies stain COS cells transfected with LL5ß but not untransfected cells (Fig. S1 B, available at http://www.jcb.org/cgi/content/full/jcb.200411012/DC1). (b) Antibody staining patterns of untransfected muscle fibers match GFP fluorescence patterns in muscle fibers transfected with the LL5ß-GFP fusion (compare Figs. 4 B and 5 A). (c) There is a similar correspondence for cultured muscle cells. (d) Two of the three antibodies (7E3 and 1H12) detect a single band on immunoblots of C2 myotube lysates (Fig. S1 A). This is the expected size for LL5ß. Results using antibody 1H12 (IgG1 subclass) are shown here, but similar results were obtained with 6B9 and 7E3.
Histology
Whole mount in situ hybridization was performed as described by Wilkinson and Nieto (1993) using digoxygenin-labeled cRNA probes. Digoxygenin was detected with alkaline phosphatase-conjugated anti-digoxygenin antibody (Roche), and signal was developed with NBT plus BCIP.
For immunohistochemistry, mouse or rat muscles were fixed in 1% PFA, sunk in 30% sucrose/PBS, frozen, and sectioned at 10 µm in a cryostat. Sections were stained sequentially with anti-LL5ß and a mixture of Alexa 488conjugated secondary antibody and rBTX or Alexa 596BTX (Molecular Probes).
Electroporation in vivo
Mouse LL5ß cDNA was obtained from American Type Culture Collection (IMAGE clone 6405379). Full-length and PH domaindeleted coding sequences (lacking aa 11941302) were amplified by RT-PCR and ligated to the BglIISalI site of pEGFP-C1 vector (CLONTECH Laboratories, Inc.). Inserts were sequenced. Plasmids were introduced into tibialis muscles of P10 mice by electroporation as described by Grady et al. (2003). 4 d after electroporation, muscles were dissected under a fluorescent stereomicroscope, fixed in 4% PFA, counterstained with BTX, and imaged with a confocal laser scanning microscope (model FV500; Olympus) using a 100x oil objective (NA 1.40).
Tissue culture
C2C12 myoblasts (American Type Culture Collection) were plated on Labtek 8-well Permanox chamber slides (Nalge) coated with 0.2% gelatin (Bio-Rad Laboratories) or 10 µg/ml laminin-1 (Invitrogen) as described by Kummer et al. (2004). Where indicated, myoblasts were transfected on the day of plating using FuGENE6 (Roche). One day after plating, cultures were switched to DME plus 2% horse serum to induce fusion. Cultured myotubes were stained live with 1 µg/ml rBTX for 30 min, and then fixed, permeabilized, and stained with anti-LL5ß and anti-GFP (Chemicon). Images collected with a CCD camera (model MagnaFire; Optronics) were analyzed with Metamorph software (Universal Imaging Corp.).
To suppress LL5ß expression, siRNA sequences were selected using SVM RNAi software (Chang Bioscience), siRNA DESIGN Center (Dharmacon), and the siRNA Selection Server at the Whitehead Institute (Massachusetts Institute of Technology, Cambridge, MA; http://jura.wi.mit.edu/siRNAext/). The mouse genome was searched with selected sequences to ensure their specificity. RNA duplexes of the following target sequences were purchased from Dharmacon: No. 1, AACCUCCUAUUUCUUUCCUCA; No. 2, AAGCCUAAGACAGUCGUCAGA; No. 3, AAGACUUGGAAUUCCAGCAGC; and No. 4, AAGCAAGCCAGUCACAUCGUU. COS-7 cells were cotransfected with an expression vector encoding GFP-LL5ß plus one of these RNAs, or control duplexes VII (57% GC Content) or VIII (52% GC Content; Dharmacon), using Lipofectamine 2000 (Invitrogen). RNAs Nos. 1 and 2 suppressed expression of GFP-LL5ß dramatically; RNA No. 4 had a less dramatic effect; and RNA No. 3 and control duplexes VII and VIII had no obvious effect on GFP-LL5ß expression. RNAs Nos. 1, 2, and 4 had no effect on expression of GFP alone, indicating that their effects were specific; the susceptibility of GFP cDNA to RNAi suppression was demonstrated with RNAi specific for GFP.
Based on these results, sequences of RNA Nos. 1 and 2 and GFP RNAi were cloned into a plasmid-based siRNA-expression system (pSuper vector; Oligoengine). Plasmids were used rather than oligonucleotides because they were superior for maintaining high expression of the interfering sequences throughout the week-long culture period. Myotubes were transfected at the time of plating using FuGene6 reagent (Roche) according to manufacturer's instructions. A total of 6.6 µl FuGene reagent and 2.2 µg DNA in 100 µl DME was used to transfect every two wells of an 8-well chamber slide. Cells were switched to differentiation medium 1 d after transfection and cultured for an additional 56 d. Cells were then stained live with a fluorescent conjugate of BTX plus, where appropriate, anti-GFP.
Online supplemental material
Fig. S1 shows evidence for specificity of anti-LL5ß antibodies. Table S1 shows the ratio of synaptic to extrasynaptic signal for each synaptic gene from each microarray experiment. These ratios were then ranked to give the values presented in Table I. Table S2 shows transcripts enriched greater than threefold in synaptic compared with extrasynaptic samples. Rankings and ratios, calculated as in Table I and Table S1, respectively, are shown, along with UniGene number (http://www.ncbi.nlm.nih.gov) and gene name. Online supplemental material is available at http://www.jcb.org/cgi/content/full/jcb.200411012/DC1.
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Acknowledgments |
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This work was funded by grants to J.R. Sanes from the National Institutes of Health. T.T. Kummer is a student in the Medical Scientist Training Program at Washington University.
Submitted: 2 November 2004
Accepted: 7 March 2005
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References |
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![]() ![]() ![]() ![]() ![]() ![]() ![]() |
---|
Altiok, N., J.L. Bessereau, and J.P. Changeux. 1995. ErbB3 and ErbB2/neu mediate the effect of heregulin on acetylcholine receptor gene expression in muscle: differential expression at the endplate. EMBO J. 14:42584266.[Abstract]
Barrantes, F.J. 2002. Lipid matters: nicotinic acetylcholine receptor-lipid interactions. Mol. Membr. Biol. 19:277284.[CrossRef][Medline]
Belvindrah, R., G. Rougon, and G. Chazal. 2002. Increased neurogenesis in adult mCD24-deficient mice. J. Neurosci. 22:35943607.
Bloch, R.J., and Z.W. Hall. 1983. Cytoskeletal components of the vertebrate neuromuscular junction: vinculin, -actinin, and filamin. J. Cell Biol. 97:217223.[Abstract]
Bloch, R.J., and D.W. Pumplin. 1988. Molecular events in synaptogenesis: nerve-muscle adhesion and postsynaptic differentiation. Am. J. Physiol. 254:C345C364.[Medline]
Breitling, R., P. Armengaud, A. Amtmann, and P. Herzyk. 2004. Rank products: a simple, yet powerful, new method to detect differentially regulated genes in replicated microarray experiments. FEBS Lett. 573:8392.[CrossRef][Medline]
Calaora, V., G. Chazal, P.J. Nielsen, G. Rougon, and H. Moreau. 1996. mCD24 expression in the developing mouse brain and in zones of secondary neurogenesis in the adult. Neuroscience. 73:581594.[CrossRef][Medline]
Carlsson, L., Z. Li, D. Paulin, and L.E. Thornell. 1999. Nestin is expressed during development and in myotendinous and neuromuscular junctions in wild type and desmin knock-out mice. Exp. Cell Res. 251:213223.[CrossRef][Medline]
Chakkalakal, J.V., and B.J. Jasmin. 2003. Localizing synaptic mRNAs at the neuromuscular junction: it takes more than transcription. Bioessays. 25:2531.[CrossRef][Medline]
Covault, J., J.P. Merlie, C. Goridis, and J.R. Sanes. 1986. Molecular forms of N-CAM and its RNA in developing and denervated skeletal muscle. J. Cell Biol. 102:731739.[Abstract]
Coy, J.F., S. Wiemann, I. Bechmann, D. Bachner, R. Nitsch, O. Kretz, H. Christiansen, and A. Poustka. 2002. Pore membrane and/or filament interacting like protein 1 (POMFIL1) is predominantly expressed in the nervous system and encodes different protein isoforms. Gene. 290:7394.[CrossRef][Medline]
Dmytrenko, G.M., D.W. Pumplin, and R.J. Bloch. 1993. Dystrophin in a membrane skeletal network: localization and comparison to other proteins. J. Neurosci. 13:547558.[Abstract]
Dowler, S., R.A. Currie, D.G. Campbell, M. Deak, G. Kular, C.P. Downes, and D.R. Alessi. 2000. Identification of pleckstrin-homology-domain-containing proteins with novel phosphoinositide-binding specificities. Biochem. J. 351:1931.[CrossRef][Medline]
Dulac, C., and R. Axel. 1995. A novel family of genes encoding putative pheromone receptors in mammals. Cell. 83:195206.[CrossRef][Medline]
Finn, A.J., G. Feng, and A.M. Pendergast. 2003. Postsynaptic requirement for Abl kinases in assembly of the neuromuscular junction. Nat. Neurosci. 6:717723.[CrossRef][Medline]
Fromm, L., and S.J. Burden. 1998. Synapse-specific and neuregulin-induced transcription require an ets site that binds GABPalpha/GABPbeta. Genes Dev. 12:30743083.
Gatchalian, C.L., M. Schachner, and J.R. Sanes. 1989. Fibroblasts that proliferate near denervated synaptic sites in skeletal muscle synthesize the adhesive molecules tenascin(J1), N-CAM, fibronectin, and a heparan sulfate proteoglycan. J. Cell Biol. 108:18731890.[Abstract]
Gautam, M., P.G. Noakes, J. Mudd, M. Nichol, G.C. Chu, J.R. Sanes, and J.P. Merlie. 1995. Failure of postsynaptic specialization to develop at neuromuscular junctions of rapsyn-deficient mice. Nature. 377:232236.[CrossRef][Medline]
Goldman, D., and J. Staple. 1989. Spatial and temporal expression of acetylcholine receptor RNAs in innervated and denervated rat soleus muscle. Neuron. 3:219228.[CrossRef][Medline]
Goldman, D., H.R. Brenner, and S. Heinemann. 1988. Acetylcholine receptor alpha-, beta-, gamma-, and delta-subunit mRNA levels are regulated by muscle activity. Neuron. 1:329333.[CrossRef][Medline]
Grady, R.M., M. Akaaboune, A.L. Cohen, M.M. Maimone, J.W. Lichtman, and J.R. Sanes. 2003. Tyrosine-phosphorylated and nonphosphorylated isoforms of -dystrobrevin: roles in skeletal muscle and its neuromuscular and myotendinous junctions. J. Cell Biol. 160:741752.
Hall, Z.W. 1973. Multiple forms of acetylcholinesterase and their distribution in endplate and non-endplate regions of rat diaphragm muscle. J. Neurobiol. 4:343361.[CrossRef][Medline]
Han, H., P.G. Noakes, and W.D. Phillips. 1999. Overexpression of rapsyn inhibits agrin-induced acetylcholine receptor clustering in muscle cells. J. Neurocytol. 28:763775.[CrossRef][Medline]
Hekimi, S., and D. Kershaw. 1993. Axonal guidance defects in a Caenorhabditis elegans mutant reveal cell-extrinsic determinants of neuronal morphology. J. Neurosci. 13:42544271.[Abstract]
Hippenmeyer, S., N.A. Shneider, C. Birchmeier, S.J. Burden, T.M. Jessell, and S. Arber. 2002. A role for neuregulin1 signaling in muscle spindle differentiation. Neuron. 36:10351049.[CrossRef][Medline]
Imaizumi-Scherrer, T., D.M. Faust, J.C. Benichou, R. Hellio, and M.C. Weiss. 1996. Accumulation in fetal muscle and localization to the neuromuscular junction of cAMP-dependent protein kinase A regulatory and catalytic subunits RI and C
. J. Cell Biol. 134:12411254.[Abstract]
Jasmin, B.J., R.K. Lee, and R.L. Rotundo. 1993. Compartmentalization of acetylcholinesterase mRNA and enzyme at the vertebrate neuromuscular junction. Neuron. 11:467477.[CrossRef][Medline]
Jessen, K.R., and R. Mirsky. 2002. Signals that determine Schwann cell identity. J. Anat. 200:367376.[CrossRef][Medline]
Jones, M.A., and M.J. Werle. 2000. Nitric oxide is a downstream mediator of agrin-induced acetylcholine receptor aggregation. Mol. Cell. Neurosci. 16:649660.[CrossRef][Medline]
Klarsfeld, A., J.L. Bessereau, A.M. Salmon, A. Triller, C. Babinet, and J.P. Changeux. 1991. An acetylcholine receptor alpha-subunit promoter conferring preferential synaptic expression in muscle of transgenic mice. EMBO J. 10:625632.[Abstract]
Kleene, R., H. Yang, M. Kutsche, and M. Schachner. 2001. The neural recognition molecule L1 is a sialic acid-binding lectin for CD24, which induces promotion and inhibition of neurite outgrowth. J. Biol. Chem. 276:2165621663.
Koike, S., L. Schaeffer, and J.P. Changeux. 1995. Identification of a DNA element determining synaptic expression of the mouse acetylcholine receptor delta-subunit gene. Proc. Natl. Acad. Sci. USA. 92:1062410628.
Kummer, T.T., T. Misgeld, J.W. Lichtman, and J.R. Sanes. 2004. Nerve-independent formation of a topologically complex postsynaptic apparatus. J. Cell Biol. 164:10771087.
Lemmon, M.A., and K.M. Ferguson. 2000. Signal-dependent membrane targeting by pleckstrin homology (PH) domains. Biochem. J. 350:118.[CrossRef][Medline]
Lipshutz, R.J., S.P. Fodor, T.R. Gingeras, and D.J. Lockhart. 1999. High density synthetic oligonucleotide arrays. Nat. Genet. 21:2024.[CrossRef][Medline]
Lockhart, D.J., H. Dong, M.C. Byrne, M.T. Follettie, M.V. Gallo, M.S. Chee, M. Mittmann, C. Wang, M. Kobayashi, H. Horton, and E.L. Brown. 1996. Expression monitoring by hybridization to high-density oligonucleotide arrays. Nat. Biotechnol. 14:16751680.[CrossRef][Medline]
Luo, Z.G., Q. Wang, J.Z. Zhou, J. Wang, Z. Luo, M. Liu, X. He, A. Wynshaw-Boris, W.C. Xiong, B. Lu, and L. Mei. 2002. Regulation of AChR clustering by Dishevelled interacting with MuSK and PAK1. Neuron. 35:489505.[CrossRef][Medline]
Luo, Z.G., H.S. Je, Q. Wang, F. Yang, G.C. Dobbins, Z.H. Yang, W.C. Xiong, B. Lu, and L. Mei. 2003. Implication of geranylgeranyltransferase I in synapse formation. Neuron. 40:703717.[CrossRef][Medline]
Maes, T., A. Barcelo, and C. Buesa. 2002. Neuron navigator: a human gene family with homology to unc-53, a cell guidance gene from Caenorhabditis elegans. Genomics. 80:2130.[CrossRef][Medline]
Martin, K.C., and K.S. Kosik. 2002. Synaptic taggingwho's it? Nat. Rev. Neurosci. 3:813820.[CrossRef][Medline]
Merlie, J.P., and J.R. Sanes. 1985. Concentration of acetylcholine receptor mRNA in synaptic regions of adult muscle fibres. Nature. 317:6668.[CrossRef][Medline]
Merlie, J.P., K.E. Isenberg, S.D. Russell, and J.R. Sanes. 1984. Denervation supersensitivity in skeletal muscle: analysis with a cloned cDNA probe. J. Cell Biol. 99:332335.
Merrill, R.A., L.A. Plum, M.E. Kaiser, and M. Clagett-Dame. 2002. A mammalian homolog of unc-53 is regulated by all-trans retinoic acid in neuroblastoma cells and embryos. Proc. Natl. Acad. Sci. USA. 99:34223427.
Miner, J.H., and J.R. Sanes. 1994. Collagen IV 3,
4, and
5 chains in rodent basal laminae: sequence, distribution, association with laminins, and developmental switches. J. Cell Biol. 127:879891.[Abstract]
Morrison, T.B., J.J. Weis, and C.T. Wittwer. 1998. Quantification of low-copy transcripts by continuous SYBR Green I monitoring during amplification. Biotechniques. 24:954958.[Medline]
Moscoso, L.M., G.C. Chu, M. Gautam, P.G. Noakes, J.P. Merlie, and J.R. Sanes. 1995a. Synapse-associated expression of an acetylcholine receptor-inducing protein, ARIA/heregulin, and its putative receptors, ErbB2 and ErbB3, in developing mammalian muscle. Dev. Biol. 172:158169.[CrossRef][Medline]
Moscoso, L.M., J.P. Merlie, and J.R. Sanes. 1995b. N-CAM, 43K-rapsyn, and S-laminin mRNAs are concentrated at synaptic sites in muscle fibers. Mol. Cell. Neurosci. 6:8089.[CrossRef][Medline]
Niehrs, C., and N. Pollet. 1999. Synexpression groups in eukaryotes. Nature. 402:483487.[CrossRef][Medline]
Paranavitane, V., W.J. Coadwell, A. Eguinoa, P.T. Hawkins, and L. Stephens. 2003. LL5beta is a phosphatidylinositol (3,4,5)-trisphosphate sensor that can bind the cytoskeletal adaptor, gamma-filamin. J. Biol. Chem. 278:13281335.
Patton, B.L., J.H. Miner, A.Y. Chiu, and J.R. Sanes. 1997. Distribution and function of laminins in the neuromuscular system of developing, adult, and mutant mice. J. Cell Biol. 139:15071521.
Peeters, P.J., A. Baker, I. Goris, G. Daneels, P. Verhasselt, W.H. Luyten, J.J. Geysen, S.U. Kass, and D.W. Moechars. 2004. Sensory deficits in mice hypomorphic for a mammalian homologue of unc-53. Brain Res. Dev. Brain Res. 150:89101.[Medline]
Peters, M.F., N.R. Kramarcy, R. Sealock, and S.C. Froehner. 1994. beta 2-Syntrophin: localization at the neuromuscular junction in skeletal muscle. Neuroreport. 5:15771580.[Medline]
Pumplin, D.W., and R.J. Bloch. 1983. Lipid domains of acetylcholine receptor clusters detected with saponin and filipin. J. Cell Biol. 97:10431054.[Abstract]
Sanes, J.R., and J.W. Lichtman. 1999. Development of the vertebrate neuromuscular junction. Annu. Rev. Neurosci. 22:389442.[CrossRef][Medline]
Sanes, J.R., and J.W. Lichtman. 2001. Induction, assembly, maturation and maintenance of a postsynaptic apparatus. Nat. Rev. Neurosci. 2:791805.[CrossRef][Medline]
Sanes, J.R., Y.R. Johnson, P.T. Kotzbauer, J. Mudd, T. Hanley, J.C. Martinou, and J.P. Merlie. 1991. Selective expression of an acetylcholine receptor-lacZ transgene in synaptic nuclei of adult muscle fibers. Development. 113:11811191.[Abstract]
Schaeffer, L., N. Duclert, M. Huchet-Dymanus, and J.P. Changeux. 1998. Implication of a multisubunit Ets-related transcription factor in synaptic expression of the nicotinic acetylcholine receptor. EMBO J. 17:30783090.
Schaeffer, L., de Kerchove d'Exaerde, A., and J.P. Changeux. 2001. Targeting transcription to the neuromuscular synapse. Neuron. 31:1522.[CrossRef][Medline]
Scher, M.G., and R.J. Bloch. 1991. The lipid bilayer of acetylcholine receptor clusters of cultured rat myotubes is organized into morphologically distinct domains. Exp. Cell Res. 195:7991.[CrossRef][Medline]
Shadiack, A.M., and R.M. Nitkin. 1991. Agrin induces alpha-actinin, filamin, and vinculin to co-localize with AChR clusters on cultured chick myotubes. J. Neurobiol. 22:617628.[Medline]
Sharrocks, A.D. 2001. The ETS-domain transcription factor family. Nat. Rev. Mol. Cell Biol. 2:827837.[CrossRef][Medline]
Sheng, M., and M.J. Kim. 2002. Postsynaptic signaling and plasticity mechanisms. Science. 298:776780.
Shewan, D., V. Calaora, P. Nielsen, J. Cohen, G. Rougon, and H. Moreau. 1996. mCD24, a glycoprotein transiently expressed by neurons, is an inhibitor of neurite outgrowth. J. Neurosci. 16:26242634.[Abstract]
Simon, A.M., P. Hoppe, and S.J. Burden. 1992. Spatial restriction of AChR gene expression to subsynaptic nuclei. Development. 114:545553.[Abstract]
Steward, O. 1983. Polyribosomes at the base of dendritic spines of central nervous system neuronstheir possible role in synapse construction and modification. Cold Spring Harb. Symp. Quant. Biol. 48:745759.[Medline]
Steward, O., and E.M. Schuman. 2001. Protein synthesis at synaptic sites on dendrites. Annu. Rev. Neurosci. 24:299325.[CrossRef][Medline]
Stringham, E., N. Pujol, J. Vandekerckhove, and T. Bogaert. 2002. unc-53 controls longitudinal migration in C. elegans. Development. 129:33673379.[Medline]
Tietjen, I., J.M. Rihel, Y. Cao, G. Koentges, L. Zakhary, and C. Dulac. 2003. Single-cell transcriptional analysis of neuronal progenitors. Neuron. 38:161175.[CrossRef][Medline]
Tusher, V.G., R. Tibshirani, and G. Chu. 2001. Significance analysis of microarrays applied to the ionizing radiation response. Proc. Natl. Acad. Sci. USA. 98:51165121.
Vaittinen, S., R. Lukka, C. Sahlgren, J. Rantanen, T. Hurme, U. Lendahl, J.E. Eriksson, and H. Kalimo. 1999. Specific and innervation-regulated expression of the intermediate filament protein nestin at neuromuscular and myotendinous junctions in skeletal muscle. Am. J. Pathol. 154:591600.
Valenzuela, D.M., T.N. Stitt, P.S. DiStefano, E. Rojas, K. Mattsson, D.L. Compton, L. Nunez, J.S. Park, J.L. Stark, D.R. Gies, et al. 1995. Receptor tyrosine kinase specific for the skeletal muscle lineage: expression in embryonic muscle, at the neuromuscular junction, and after injury. Neuron. 15:573584.[CrossRef][Medline]
Velleca, M.A., M.C. Wallace, and J.P. Merlie. 1994. A novel synapse-associated noncoding RNA. Mol. Cell. Biol. 14:70957104.[Abstract]
Weston, C., B. Yee, E. Hod, and J. Prives. 2000. Agrin-induced acetylcholine receptor clustering is mediated by the small guanosine triphosphatases Rac and Cdc42. J. Cell Biol. 150:205212.
Wilkinson, D.G., and M.A. Nieto. 1993. Detection of messenger RNA by in situ hybridization to tissue sections and whole mounts. Methods Enzymol. 225:361373.[Medline]
Wilson, M.D., C. Riemer, D.W. Martindale, P. Schnupf, A.P. Boright, T.L. Cheung, D.M. Hardy, S. Schwartz, S.W. Scherer, L.C. Tsui, et al. 2001. Comparative analysis of the gene-dense ACHE/TFR2 region on human chromosome 7q22 with the orthologous region on mouse chromosome 5. Nucleic Acids Res. 29:13521365.
Wittwer, C.T., M.G. Herrmann, A.A. Moss, and R.P. Rasmussen. 1997. Continuous fluorescence monitoring of rapid cycle DNA amplification. Biotechniques. 22:130131, 134138.
Yoshihara, C.M., and Z.W. Hall. 1993. Increased expression of the 43-kD protein disrupts acetylcholine receptor clustering in myotubes. J. Cell Biol. 122:169179.[Abstract]
Zhu, X., C. Lai, S. Thomas, and S.J. Burden. 1995. Neuregulin receptors, erbB3 and erbB4, are localized at neuromuscular synapses. EMBO J. 14:58425848.[Abstract]
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