Baldwin TJ , Yoshihara CM , Blackmer K , Kintner CR , Burden SJ .

NS 21579 NINDS NIH HHS , R01 NS021579-14 NINDS NIH HHS , R01 NS021579 NINDS NIH HHS

	Figure 1. Restriction map, sequencing strategy, nucleotide sequence, and deduced amino acid sequence of the alpha, gamma, and delta subunits of the Xenopus laevis skeletal muscle AChR. (Le~) Restriction map and sequencing strategy of the alpha, gamma, and delta subunits. Numbers indicate the 5' terminal nucleotide generated by cleavage. (Below and right) Nucleotide and deduced amino acid sequence of the alpha, gamma, and delta subunits. Nucleotide 1 indicates the first nucleotide of the codon encoding the amino terminal residue in the mature protein and nucleotides to the 5' side of this amino terminal residue are indicated with negative numbers. The number of the nucleotide residue at the end of each line is provided. The predicted amino acid sequence is shown above the nucleotide sequence. Amino acid residues are numbered beginning with the amino terminal residue of the mature protein and the preceeding amino acids of the signal sequence are indicated with negative numbers. Since mRNA encoding each subunit is longer than the corresponding cDNA, these sequences are incomplete.
	Figure 2. Alpha subunit transcript is confined to the somites of Xenopus embryos. (a) Bright-field optics of Giemsa-stained transverse section of stage 26 Xenopus embryo illustrates the neural tube (nt), notochord (n), somites (s), and epidermis (ep). (b) Dark-field optics illustrates the position of the autoradiographic grains, which are highly concentrated over the somites and not present over other tissue at a level higher than background. Bar, 50 ~tm.
	Figure 3. Northern blot analysis of poly(A) + RNA from Xenopus embryos. 1 gg of poly(A) + RNA isolated from stage 41 Xenopus embryos was fractionated by eleetrophoresis in a formaldehyde agarose (1%) gel, transferred to Zetabind, and hybridized to 32p-labeled AChR alpha (a), gamma ('D or delta subunit (6) cDNA probes (Materials and Methods). This filter was washed at moderate stringency (Materials and Methods). The RNAs that hybridize to the alpha, gamma, and delta probes migrate at 2.3 (tt), 2.4 (~/), and 1.9/ 2.5 kb (6), respectively. Washing at higher stringency did not reduce hybridization to AChR transcripts. The positions of RNA standards (4.4, 2.4, and 1.4 kb) are indicated at right. The pattern of Northern blots from earlier stages (stages 20 and 25) were identical to those from stage 41 embryo RNA except that gamma subunit transcript levels were comparable to those of alpha and delta at earlier stages. The filter was exposed to x-ray film with an intensifying screen at -70~ for 4 d.
	Figure 4. AChR transcripts are expressed at late gastrula. RNA from 25 embryo equivalents was included in hybridizations with 32p-labeled AChR subunit probes, whereas RNA from 2.5 embryo equivalents was included in hybridizations with the 32p-labeled cardiac actin probe (AC). A single batch of RNA isolated from each stage was used in protection assays with each probe, except that a different batch of stage 18 RNA was used in the protection as~y with the delta subunit probe. This second batch of stage 18 RNA contained less total RNA per embryo and correspondingly less actin mRNA per embryo. Quantitation of transcript levels is presented in Table I. The positions of protected fragments are indicated with arrowheads; the positions of the minor protected fragments in hybridizations with the delta subunit probe are indicated with arrows. The standard curve for delta subunit RNA is illustrated (std) and includes 0.5, 2.0, 5.0, and 10 pg of synthetic delta RNA. Developmental stages are indicated at the top of each lane; neither AChR nor actin mRNA was detected in eggs (lane E). Gels were exposed to x-ray films with an intensifying screen at -70~ for 70 h (actin) or 7 d (AChR).
	Figure 5. Gamma subunit transcript levels are regulated differently than alpha and delta subunit transcript levels. RNA from 10 embryo equivalents was included in hybridizations with 32p-labeled AChR subunit probes, whereas RNA from 1 embryo equivalent was included in hybridizations with the 32p-labeled cardiac actin probe (AC). A single batch of RNA isolated from each stage was used in protection assays with each probe, except that a different batch of stage 25 RNA was used in the protection assay with the delta subunit probe. This second batch of stage 25 RNA contained less total RNA per embryo and correspondingly less actin mRNA per embryo. Quantitation of transcript levels is presented in Table I. Developmental stages are indicated at the top of each lane; neither AChR nor actin mRNA was detected in eggs (lane E). The positions of protected fragments are indicated with arrowheads. Gels were exposed to x-ray films with an intensifying screen at -70~ for 6.5 (actin) or 16 h (AChR).
	Figure 6. Embryos that remain nonmotile throughout development express normal levels of AChR transcripts. 50 gg of embryo RNA (10 embryo equivalents for all samples) was included in hybridizations with 32p-labeled AChR probes, whereas 5 gg of embryo RNA was included in hybridizations with 32p-labeled cardiac actin probe (AC). Developmental stages are indicated at the top of each lane; t indicates RNA from embryos that were paralyzed with tricaine. The positions of protected fragments are indicated with arrowheads. Gels were exposed to x-ray films with an intensifying screen at -70~ for 6.5 (actin) or 16 h (AChR).
	Figure 7. Alpha subunit transcript levels increase 100-fold in denervated adult muscle. The triceps femoris muscle of adult Xenopus was denervated and alpha subunit transcript levels in normal and denervated muscle were measured by RNase protection (Materials and Methods). The amount of alpha transcript in normal, innervated muscle (INN) is low and increases 100-fold in denervated muscle (DEN), whereas the amount of total mRNA as determined for Ef-1 alpha transcript in normal, innerva~xl (INN), and denervated muscle (DEN) is indistinguishable. There is no protection of either probe in hybridizations with tRNA. The positions of protected fragments are indicated with arrowheads. The gels were exposed to x-ray films with an intensifying screen at -70~ for 1 d.

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