Targeting of the ETS Factor Gabp{alpha} Disrupts Neuromuscular Junction Synaptic Function

The GA-binding protein (GABP) transcription factor has beenshown in vitro to regulate the expression of the neuromuscularproteins utrophin, acetylcholine esterase, and acetylcholinereceptor subunits ${delta}$ and ${varepsilon}$ through the N-box promoter motif (5'-CCGGAA-3'),but its in vivo function remains unknown. A single point mutationwithin the N-box of the gene encoding the acetylcholine receptor ${varepsilon}$ subunit has been identified in several patients suffering frompostsynaptic congenital myasthenic syndrome, implicating theGA-binding protein in neuromuscular function and disease. Sinceconventional gene targeting results in an embryonic-lethal phenotype,we used conditional targeting to investigate the role of GABP ${alpha}$ in neuromuscular junction and skeletal muscle development. Thediaphragm and soleus muscles from mutant mice display alterationsin morphology and distribution of acetylcholine receptor clustersat the neuromuscular junction and neurotransmission propertiesconsistent with reduced receptor function. Furthermore, we confirmeddecreased expression of the acetylcholine receptor ${varepsilon}$ subunitand increased expression of the ${gamma}$ subunit in skeletal muscletissues. Therefore, the GABP transcription factor aids in thestructural formation and function of neuromuscular junctionsby regulating the expression of postsynaptic genes.

INTRODUCTION

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INTRODUCTION

Congenital myasthenic syndrome (CMS), is a heterogeneous disorderof neuromuscular transmission that occurs at a frequency of<1/500,000 people (42). CMS can be classified as presynaptic(i.e., choline acetyltransferase gene mutations), synaptic (i.e.,acetylcholine esterase gene [AChE] mutations), or postsynaptic(i.e., acetylcholine receptor gene [AChR], or Rapsyn, mutations)in origin (14). All cases of CMS identified so far result inmuscle weakness due to a lack of propagation of the endplatepotential (13, 14). Understanding the molecular basis of CMS,and other neuromuscular diseases, may lead to the identificationof potential therapies.

CMS is usually caused by missense mutations in the coding regionsof neuromuscular junction (NMJ) proteins, such as ACh, AChE,or AChR subunits (30), or in postsynaptic AChR-associated proteins,such as Rapsyn (33). These mutations often result in structuralchanges of the AChR and altered affinity for ACh (34). In addition,a homozygous mutation in the N-box element (5'-CCGGAA-3') ofthe AChR ${varepsilon}$ promoter results in a decreased number of AChRs andclinical symptoms of CMS (30, 32). This C $->$ T transition in themouse AChR ${varepsilon}$ promoter results in a 90% decrease in binding ofthe ETS transcription factor GA-binding protein (Gabp) (10).

The widely expressed ETS transcription factor Gabp regulatesgenes essential for the function of the NMJ, such as AChR ${delta}$ and- ${varepsilon}$ (10, 23), AChE (3), and Utrophin (21), yet the molecular mechanismby which Gabp regulates NMJ-specific gene expression remainsto be elucidated (39). In situ hybridization reveals that Gabp ${alpha}$ mRNA is slightly enriched at NMJs relative to other muscle tissue,suggestive of synaptic function (40). The Gabp complex is composedof an ${alpha}$ subunit (containing an ETS domain that binds a 5'-GGAA-3'motif) and a ß subunit (providing a nuclear localizationsignal and a transactivation domain) (25). GABP is phosphorylatedat specific residues in both subunits in response to neuregulin-ErbBsignaling, with receptor binding resulting in activation ofthe ERK and JNK serine-threonine kinases and, subsequently,the GABP complex, which then binds the N-box promoter elementsof target genes (17).

Skeletal-muscle-specific, ETS dominant-negative mice exhibitmuscles with small AChR patches and disorganized postsynapticjunctional folds (7). However, the ETS factor responsible forthis phenotype was not identified. Our studies suggest thatGabp ${alpha}$ is a likely candidate. Mice deficient in Gabp ${alpha}$ die priorto implantation (35), thus restricting the use of these miceto prove a function for Gabp in AChR regulation in vivo. Inthis study, we examine the role of Gabp in skeletal muscle developmentand function by conditional targeting of Gabp ${alpha}$ . These mice demonstratedefects in AChR assembly and synaptic transmission at the NMJin skeletal muscle, highlighting the importance of Gabp in thedevelopment and function of postsynaptic structures at the NMJ.

MATERIALS AND METHODS

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MATERIALS AND METHODS

Generation of a Gabp ${alpha}$ targeting construct. A 3.2-kb BamHI-EcoRI genomic fragment, spanning introns 1 and2 of Gabp ${alpha}$ (bp 6662 to 9873 of GenBank accession no. GI:27960443),was inserted into the pBS KS⁺ vector (Stratagene, La Jolla,CA) and constituted the 5' and 3' homologous sequences of thetargeting construct. Exon 2 of Gabp ${alpha}$ was removed by BclI digestion(bp 8212 to 8572 of GI:27960443) (35) and replaced with a 1.4-kbApaI-NsiI fragment encompassing the floxed pMCI-Neomycin cassette.Finally, a 380-bp PCR product containing Gabp ${alpha}$ exon 2 fused toa loxP site at its 5' end (spanning bp 8220 to 8562 of GI:27960443)was inserted at a unique AatII site at the 5' end of the Neomycincassette. A negative selection marker, thymidine kinase, underthe control of the Herpes simplex virus promoter, was introducedinto the pBS KS(+) vector backbone at a unique XhoI site.

Generation of Gabp ${alpha}$ floxed mice. Embryonic stem (ES) cells from mice of the SvJ129 backgroundstrain were electroporated with the Gabp ${alpha}$ targeting construct(linearized at a SacII site within the vector backbone) andselected for 7 days using Geneticin at 15 mg/ml and ganciclovirat 2 µM, as previously described (24). Selected colonieswere screened by Southern blotting and subsequently electroporatedwith PGK-Cre recombinase and PGK-puromycin constructs. Conditionallytargeted (floxed) ES cell clones were screened by PCR followingselection with 3 µg/ml puromycin for 2 days prior to injectioninto blastocysts from superovulated C57BL/6 female mice.

ES cell screening and generation of Gabp ${alpha}$ floxed ES cells. Ten micrograms of genomic DNA was digested with 10 U BamHI overnightat 37°C prior to electrophoresis and Southern blot capillarytransfer onto Gene Screen Plus nylon membrane (NEN, Boston,MA) according to the manufacturer's instructions. The membraneswere hybridized as previously described (19), using a 977-bpSacII-SpeI probe within Gabp ${alpha}$ intron 3 (bp 12695 to 13672 ofGI:27960443) to identify a 7-kb wild-type and a 5-kb targetedfragment, respectively. ES cell clones were screened by PCRspanning intron 1 and intron 2 (primers G1f, 5'- GCTGTGCTTTGCCAGTGTTG-3',and G1r, 5'-GACTAAGTGAGGACTATTGG-3'), generating 1.5-kb, 1.8-kb,and 1.9-kb fragments from the knockout, wild-type, and floxedalleles, respectively. The presence of the single loxP siteimmediately upstream of exon 2 was confirmed by multiplex PCR,using a common 5' primer within intron 1 (G2f, 5'-CTCCTGAGGTCCCTGCTTTG-3')and 3' primers within exon 2 (G2r, 5'-GTCCCGTCGATCTCAATTTC-3')and intron 2 (G1r, 5'-GACTAAGTGAGGACTATTGG-3'). This reactiongenerated 620-bp, 660-bp, and 740-bp fragments representingwild-type, floxed, and knockout Gabp ${alpha}$ alleles, respectively.

Generation of Gabp ${alpha}$ skeletal-muscle-specific knockout mice. Gabp ${alpha}$ floxed mice were intercrossed with mice expressing theCre recombinase transgene driven by the promoter of the human ${alpha}$ -skeletal actin gene (described in reference 28) to generateheterozygous conditional-knockout mice of genotype Gabp ${alpha}$ ^F/+ HSA^cre/+.These mice (referred to here as +/–) were intercrossedto confirm a Mendelian ratio of allelic inheritance. Animalsused for phenotypic analysis were generated from breeding homozygousfloxed animals (Gabp ${alpha}$ ^F/F, referred to as wild type, or +/+, unlessotherwise defined) with homozygous conditional mutant mice (Gabp ${alpha}$ ^F/FHSA^cre/+, referred to as –/–). Genomic DNA was screenedby PCR using 0.25 U Taq DNA Polymerase (Promega, Madison, WI),with annealing at 50°C and a 1-min extension time. Gabp ${alpha}$ alleles were amplified with primers G2f, G2r, and G1r in reactionmixtures containing 2 mM MgCl₂. The Cre allele was detectedby amplification with primers Cre-5' (5'-CCGGTCGATGCAACGAGTGAT-3')and Cre-3' (5'-ACCAGAGTCATCCTTAGCGCC-3') in reaction mixturescontaining 1.5 mM MgCl₂. All experiments using mice were carriedout in accordance with Australian federal regulations and approvedby the Monash University ethics committee.

SDS-PAGE and Western blot immunodetection. Protein samples were prepared, electrophoresed through 8% nonreducingpolyacrylamide gels, and transferred onto Immobilon-P membranes(Millipore, Bedford, MA) as previously described (37). Gabp ${alpha}$ protein was detected by overnight incubation at 4°C witha rabbit polyclonal antibody generated against amino acids 40to 147 (35) and subsequent incubation with 0.15 µg/mlgoat anti-rabbit horseradish peroxidase-conjugated immunoglobulinG (IgG) (DAKO, Carpinteria, CA) for 1 h at room temperatureprior to detection with SuperSignal West Pico ChemiluminescentSubstrate (Pierce, Rockford, IL) and exposure to film (BioMaxMR; Kodak, Rochester, NY). The film was developed in a KodakX-OMAT 480 RA processor and scanned at 100 dots per inch usinga Canon N1220U, and the intensities of bands were determinedusing FujiFilm MacBAS v2.5 software. Protein levels were quantifiedas a ratio to ß-tubulin by detection with 0.05 µg/mlanti-ß-tubulin mouse monoclonal antibody (Boehringer-Mannheim,Mannheim, Germany), followed by 0.3 µg/ml rabbit anti-mousehorseradish peroxidase-IgG (DAKO, Carpinteria, CA), and resultsfrom three animals per genotype were averaged across three duplicateblots.

Real-time RT-PCR analysis. The rapid acid guanidinium thiocyanate-phenol-chloroform method(5) was used for total-RNA preparation from mouse skeletal muscletissues. Samples were treated with DNase I (Promega, Madison,WI), and $~$ 10 µg of RNA was used as a template for first-strandcDNA synthesis using avian myeloblastosis virus reverse transcriptase(Promega, Madison, WI) and oligo(dT) primer according to themanufacturer's instructions. The relative expression levelsof transcripts were determined using a Light Cycler (Roche,Mannheim, Germany) real-time reverse transcription (RT)-PCRmachine (v3.5 software) according to the manufacturer's instructionsand expressed as a ratio relative to ß-actin. Specificprimer sequences amplified the following RT-PCR products: AChR ${delta}$ ,bp 1021 to 1830 of GI:191609; AChR ${varepsilon}$ , bp 3 to 258 of GI:2660742;utrophin, bp 10381 to 10603 of GI:1934962; Rapsyn, 827 to 918bp of GI:53804; and ß-actin, bp 344 to 446 of GI:49867.

Histology and fiber typing of skeletal muscle. Slides of transverse cryosections (16 µm) of skeletalmuscle from 1-month-old mice were submerged in freshly madeNADH staining solution (1 mg/ml 4-nitro blue tetrazolium [Sigma,Saint Louis, MO] and 0.8 mg/ml NADH [Sigma, Saint Louis, MO]dissolved in 0.2 M Tris-HCl, pH 7.4) and incubated at 37°Cfor 25 min in the dark. The slides were then rinsed in distilledwater for 5 min prior to dehydration and mounting in histolene(Amber Scientific, Selmont, WA, Australia) and DePex (BDH, Poole,United Kingdom) solution. Images were taken with a Leica MPS60digital camera on a Leica DMR microscope (Leica Instruments,Nussloch, Germany) at x200 magnification.

Immunohistochemistry. Intact muscles were dissected and stained as previously described(22). For staining skeletal muscle tissue sections, dissectedorgans were rinsed in phosphate-buffered saline (PBS) and embeddeddirectly into Tissue Tek optimal-cutting-temperature compound(OCT) (Sakura, Torrance, CA). OCT blocks were slowly frozenby placement into a plastic tray filled with 100% (vol/vol)isopentane resting on a bed of dry ice. The OCT tissue blockswere stored at –80°C. Prior to use, the tissue blockswere thawed to –20°C in the cryostat chamber for 30min. Tissue was sectioned at 16 µm at –18°Cusing a Leica CM 3050 cryostat, and the tissue was collectedonto Superfrost Plus (Menzel-Glaser, Braunschweig, Germany)glass slides. Prior to tissue staining, the mounted slides werethawed to room temperature and washed in PBS for 5 min to ridthem of excess OCT compound.

AChR clusters were detected using Texas red-conjugated ${alpha}$ -bungarotoxin(Molecular Probes, Eugene, OR) at 1 µg/ml. Nerves andsynaptic terminals were localized in whole-mount samples byimmunohistochemistry with rabbit sera raised against mouse 200-kDaneurofilament (8 µg/ml; Sigma, Saint Louis, MO) and humansynaptophysin (1/50 neat sera; DAKO, Carpinteria, CA), and AChR ${delta}$ and AChR ${gamma}$ proteins were detected in tissue sections with 2 µg/mlpolyclonal rabbit antibodies sc-14000 and sc-13998 (Santa CruzBiotechnology, Santa Cruz, CA). The antibodies were then visualizedby use of 7.5 µg/ml Alexa 488-conjugated goat anti-rabbitIgG secondary antibody (Molecular Probes, Eugene, OR).

Stained fibers and tissue sections were imaged with a TCS NTdigital camera on a DMRXE confocal microscope (Leica Instruments,Nussloch, Germany). NMJ areas of z-projected confocal imageswere calculated using ImageJ software. The values representaverages of six experiments, where for the floxed control, n= 100; for the mutant type 1, n = 81; and for the mutant type2, n = 26.

¹²⁵I-labeled ${alpha}$ -bungarotoxin staining. Intact soleus muscles were dissected from 3-month-old Gabp ${alpha}$ conditional-knockoutand littermate homozygous floxed mice and fixed in 2% (wt/vol)paraformaldehyde for 1 h at room temperature. Following threerinses (5 min each) in PBS, the muscles were teased into smallfiber bundles and stained in a solution of 0.5-mg/ml acetylthiocholineiodide (Sigma, Saint Louis, MO) dissolved in 65 mM sodium acetate(pH 6.0), 1.5 mg/ml sodium citrate, 480 µg/ml cupric sulfate,and 170 µg/ml potassium ferricyanide for 30 min. Followingthree rinses (5 min each) in PBS, the synapse-rich regions weredissected away from the nonsynaptic regions of muscle fibersand then incubated in blocking solution (as described above)for 1 h at room temperature, followed by the addition of 10nM [3-¹²⁵I]iodotyrosyl- ${alpha}$ -bungarotoxin (Amersham Biosciences,Buckinghamshire, United Kingdom) for 4 h. The fibers were washedthree times in 0.5% (vol/vol) Triton X-100 in PBS, for 15 mineach time, prior to measurment of the radioactivity in a PackardCobra 5005 gamma counter. Readings obtained for nonsynapticregions were subtracted from those of synaptic regions for eachmuscle and were represented as an average of three experiments(n = 18). Means were compared using an unpaired Student's ttest; P values of less than 0.05 were taken to be statisticallysignificant.

Neuromuscular electrophysiology. Diaphragm and soleus muscles were dissected from 3-month-oldGabp ${alpha}$ conditional-knockout and littermate control homozygousfloxed mice, prepared, and stimulated as previously described(22). Extracellular recordings of the nerve terminal impulse(NTI), endplate currents (EPCs), and miniature endplate currents(MEPCs) were obtained using micropipettes (4-µm diameter).Focal extracellular recordings were obtained by adjusting theposition of the electrode until both EPCs and MEPCs with risetimes of less than 1 millisecond were detected. This methodof recording was chosen because it measures the current underlyingthe intracellular potential changes if the electrode is closeto the release site (2, 8, 16, 22); the electrode records thenerve terminal impulse as it passes along the nerve terminal,making it easy to check for action potential propagation failureas the cause for failure to release quanta (22), and the decayof the EPC gives an estimate of the closing times of many channels(11, 20). Care was taken to ensure that the frequencies of theEPCs and MEPCs did not change as the micropipette was lowered,since electrode pressure can give rise to an increase in thespontaneous frequency (16).

Once the NMJ was located, stimulation was halted for 5 min beforerecording MEPCs and EPCs to allow the terminals to replenishvesicle pools. Eight to 12 sites were selected for each musclepreparation, with at least 30 MEPCs and 100 to 200 stimulationsrecorded at each site. Four soleus muscles from each experimentalgroup were examined. Extracellular recording sites were includedfor analysis if the frequencies of EPCs and MEPCs did not changedue to electrode pressure and if at least one EPC was recordedduring the first 10 stimuli. No correction for nonlinear summationwas necessary, since all the EPCs recorded were less then 1mV (27). The quantal content was calculated using either themethods of failures (if the proportion of failure to recordan EPC was greater than 30%) (9) or by dividing the mean EPCamplitudes by the mean MEPC amplitudes (36). The rise times,decay times, and amplitudes and frequencies of evoked (EPC)and spontaneous (MEPC) releases were calculated and tabulatedfor each experimental group. The means were compared using anunpaired Student's t test; P values of less than 0.05 were takento be statistically significant.

RESULTS

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RESULTS

Generation of Gabp ${alpha}$ conditional-knockout mice. Ubiquitous knockout Gabp ${alpha}$ mice die early in embryogenesis (35).Therefore, to determine the in vivo role of Gabp ${alpha}$ in skeletalmuscle development and neuromuscular signaling, we generatedmice lacking Gabp ${alpha}$ specifically in skeletal muscle. To preventthe production of partial Gabp ${alpha}$ transcripts, we targeted exon2, the first coding exon, using the Cre-loxP system of bacteriophageP1 (41). A single loxP site was inserted immediately upstreamof exon 2, and a floxed Neomycin cassette was cloned withinintron 2 (Fig. 1A, ii). This construct was transfected intoES cells, and Southern blot analysis was used to identify fourheterozygous targeted Gabp ${alpha}$ ES clones (Fig. 1B). Transient transfectionof Cre recombinase into targeted clones 28 and 70 removed theNeomycin cassette to yield heterozygous floxed Gabp ${alpha}$ (+/loxP)(Fig. 1A, iii). These clones were identified by PCR spanningintrons 1 and 2 (Fig. 1C). ES cell clones containing the floxedGabp ${alpha}$ allele were injected into mouse blastocysts to yield chimericmice. Seven lines that transmitted the floxed Gabp ${alpha}$ allele wereidentified. All subsequent generations of mice were genotypedusing a multiplex PCR, whereby the presence or absence of Gabp ${alpha}$ exon 2 and the single remaining loxP site within intron 1 wereconfirmed by PCR amplification with primers spanning intron1 and either exon 2 (wild-type and floxed alleles) or intron2 (knockout allele) (see Fig. S1 in the supplemental material).

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FIG. 1. Conditional targeting of the Gabp ${alpha}$ locus. (A) Schematic of wild-type, targeted, floxed, and conditional-knockout Gabp ${alpha}$ alleles. A floxed Neomycin (neo) cassette was inserted within intron 2, and a single loxP site immediately upstream of exon 2. The positions of the Southern blot probe, PCR primers and restriction sites for BamHI (B), BalI (Bl), EcoRI (E), and HindIII (H) are shown. (B) Southern blot analysis of genomic DNA from G418-resistant ES cells (clone numbers are shown), using a BamHI digest and an external intron 3 probe to detect 7-kb wild-type and 5-kb targeted fragments. (C) PCR screening of puromycin-resistant targeted ES cell clones following transient Cre transfection was performed with primers G1f and G1r, spanning Gabp ${alpha}$ introns 1 and 2 flanking the site of insertion of the neo cassette, generating 1.8-kb wild-type (wt), 1.9-kb floxed (loxP), and 1.5-kb knockout (ko) allele products.

Conditional loss of Gabp ${alpha}$ expression in skeletal muscle was achievedby intercrossing mice carrying floxed Gabp ${alpha}$ and human alpha skeletalactin (h ${alpha}$ SA)-Cre alleles (Fig. 1A, iv). The h ${alpha}$ SA-Cre mouse lineexpresses Cre recombinase specifically in skeletal muscle, fromembryonic day 9.5 (28). Amplification of a 797-bp PCR productfrom the h ${alpha}$ SA-Cre allele confirmed the presence of the transgene(see Fig. S1 in the supplemental material). The resultant littersfrom these intercrosses gave the expected frequency of eachgenotype according to Mendelian inheritance (n = 410).

Loss of Gabp ${alpha}$ expression specifically in skeletal muscle. We characterized genomic DNA from various tissues and showedthat a 740-bp PCR product representing the Gabp ${alpha}$ knockout alleleis detected only in skeletal muscle tissues of heterozygousand homozygous conditional-knockout mice (Fig. 2A), consistentwith specific expression of Cre recombinase. The wild-type alleleis represented by a 620-bp band in all tissues, except skeletalmuscle of homozygous mutants, and the floxed Gabp ${alpha}$ allele isrepresented by a 660-bp band (Fig. 2A). The presence of thefloxed PCR product in skeletal muscle of homozygous mutantsindicates the presence of nonmuscle cell types in whole-tissuelysates (Fig. 2A).

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FIG. 2. Specific loss of Gabp ${alpha}$ expression in skeletal muscle. (A) PCR screening of genomic DNA extracted from organs of wild-type (+/+), heterozygous (+/–), and homozygous knockout (–/–) mice. A common 5' primer within intron 1 (G2f) and 3' primers within exon 2 (G2r) and intron 2 (G1r) generated products of 620 bp, 660 bp, and 740 bp, representing wild-type, floxed, and knockout alleles, respectively. The knockout is represented by an asterisk in each case where no wild-type allele was detectable. (B) Western blot analysis of Gabp ${alpha}$ (58-kDa) and ß-tubulin (50-kDa) protein levels in skeletal muscle tissues and primary skeletal muscle cell cultures from Gabp ${alpha}$ skeletal-muscle-specific knockout mice (–/–) relative to homozygous floxed (+/+) littermates. Severely reduced Gabp ${alpha}$ protein levels were observed in whole muscle tissue lysates of Gabp ${alpha}$ mutant mice and complete loss of Gabp ${alpha}$ protein expression in Gabp ${alpha}$ mutant primary skeletal muscle cells derived from mice at postnatal days 2 and 3.

We then examined lateral and medial gastrocnemius, soleus, vastuslateralis, and diaphragm muscles for Gabp ${alpha}$ protein expressionin floxed, heterozygous, and homozygous skeletal muscle-specificknockout mice by Western blotting (Fig. 2B shows a representativeblot). Gabp ${alpha}$ protein levels, quantified relative to ß-tubulin(see Fig. S2 in the supplemental material), demonstrated a significantreduction (P < 0.05; n = 3; Student two-tailed t test) inGabp ${alpha}$ expression in all muscles examined from homozygous Gabp ${alpha}$ skeletal muscle-specific knockout mice, ranging from 25 to 55%of normal levels in the soleus and diaphragm, respectively.Gabp ${alpha}$ expression levels in heterozygous mice also varied in atissue-specific manner, from 20 to 85% of normal levels in themedial gastrocnemius and diaphragm, respectively (data not shown).The residual Gabp ${alpha}$ protein detected in muscle tissues of Gabp ${alpha}$ mutant mice was likely due to heterogeneous Cre expression inmultinucleated fibers and/or the presence of nonskeletal musclecell types in these tissues. Immunohistochemistry of singleskeletal muscle fibers from adult Gabp ${alpha}$ mutant mice demonstratedvariable Cre expression (data not shown), and Western blot analysisof Gabp ${alpha}$ expression in primary skeletal muscle cultures isolatedfrom 2- to 3-day-old pups revealed undetectable protein levelsin animals homozygous for the Gabp ${alpha}$ mutation (Fig. 2B).

We also examined protein extracts for the presence of alteredGabp ${alpha}$ proteins in knockout muscle in order to confirm that conditionaltargeting and deletion of Gabp ${alpha}$ exon 2 does not result in C-terminallytruncated proteins that may produce hypomorphic or dominant-negativefunctions of Gabp. We performed Western analysis with a monoclonalantibody generated against the C terminus of Gabp ${alpha}$ (a kind giftof S. Burden, The Skirball Institute). This antibody detecteda protein product of a size similar to that of our N-terminalantibody, and there were no smaller (potentially truncated)proteins detected in knockout muscle (data not shown). Giventhat the ATP synthase coupling factor 6 gene is proximal toGabp ${alpha}$ and the two genes are known to share some common regulatoryelements (4), we examined whether conditional targeting of Gabp ${alpha}$ resulted in disruption of and or aberrant expression of ATPsynthase coupling factor 6. Real-time RT-PCR analysis revealedno difference in expression levels between wild-type, homozygousfloxed, and homozygous knockout muscles (data not shown).

Phenotype analysis of skeletal-muscle-specific Gabp ${alpha}$ knockout mice. Gabp ${alpha}$ does not appear to be essential for the growth and developmentof skeletal muscle, as the body weights of homozygous floxedand homozygous Gabp ${alpha}$ conditional-knockout mice did not differfrom 1 to 6 months of age, and histological analysis of muscletissue from 1- to 6-month-old animals by hematoxylin and eosinstaining and DAPI (4',6'-diamidino-2-phenylindole) stainingshowed no difference in the proportions of centronucleated regeneratingfibers (data not shown). Skeletal muscle tissues were weighedat 3 months of age, and no significant difference was foundbetween homozygous floxed and homozygous Gabp ${alpha}$ conditional-knockoutmice (Fig. 3A). In addition, NADH staining of fresh transversemuscle sections revealed no atrophy of skeletal muscle fibersin Gabp ${alpha}$ mutant mice (Fig. 3B). Footprint analysis comparingthe regularity of gait of Gabp ${alpha}$ skeletal-muscle-specific knockoutand homozygous floxed mice at 1, 3, and 6 months of age alsorevealed no differences (data not shown). The lack of an overtphenotype in skeletal muscle of Gabp ${alpha}$ mutant mice may be dueto the high safety factor of neurotransmission found in micein comparison to humans (26).

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FIG. 3. (A) Organ weights of heart and various skeletal muscle tissues (lateral gastrocnemius, medial gastrocnemius, soleus, vastus lateralis, and diaphragm) showed no statistical difference between samples from 1-month-old homozygous floxed (+/+) and Gabp ${alpha}$ skeletal-muscle-specific knockout (–/–) mice. (B) NADH staining of transverse cryosections from 1-month-old homozygous floxed (+/+) and Gabp ${alpha}$ skeletal-muscle-specific knockout (–/–) mice showing no significant difference in fiber size or tissue integrity between the two genotypes. Type I, IIb, and IIa fibers are shown by dark, light, and intermediate staining, respectively. The images were taken at x200 magnification.

Gabp ${alpha}$ is necessary for normal NMJ formation. AChR distribution was analyzed (by staining with a Texas redconjugate of ${alpha}$ -bungarotoxin) in lateral and medial gastrocnemius,soleus, and vastus lateralis muscles from homozygous floxedand homozygous Gabp ${alpha}$ mutant mice at 1, 3, and 6 months of age,and no difference was apparent (data not shown), indicatingthat Gabp ${alpha}$ is not essential for the formation of postsynapticAChR clusters. We examined the gross morphology of the NMJ bywhole-mount staining for pre- and postsynaptic elements, usingantibodies to synaptophysin-neurofilament and ${alpha}$ -bungarotoxin,respectively. Individual muscle fibers were obtained from soleusmuscles from homozygous floxed and Gabp ${alpha}$ mutant mice at 3 monthsof age. As shown by the representative images in Fig. 4A, themorphologies of NMJs in Gabp ${alpha}$ mutant mice were classified intotwo groups. First, 76% of soleus NMJs of homozygous Gabp ${alpha}$ skeletal-muscle-specificknockout mice showed less branching than those of homozygousfloxed Gabp ${alpha}$ controls but appeared relatively normal and wereclassified as type 1. The remaining 24% of soleus NMJs showeda single ring structure and were classified as type 2. Similarproportions of the two classes of NMJs were observed in diaphragmand sternomastoid muscles (data not shown), but the soleus musclewas chosen for all quantification because of the relativelylarge size of the NMJs.

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FIG. 4. NMJ morphology in soleus muscles of Gabp ${alpha}$ conditional-knockout mice. (A) Whole-mount immunostaining of single muscle fibers from 3-month-old control homozygous floxed (+/+) and homozygous Gabp ${alpha}$ skeletal-muscle-specific knockout (–/–) mice. NMJ shape is revealed by AChR staining with Texas red-conjugated ${alpha}$ -bungarotoxin ( ${alpha}$ Btx). Nerves and synaptic junctions were stained with a cocktail of fluorescein isothiocyanate-conjugated antibodies against neurofilament and synaptophysin (NF-SNP). The relative positions of nerves (N), synaptic junctions (SJ), and AChRs are indicated in the top left panel. NMJs of –/– mice are classified as showing less branching than those of control mice (type 1) or single ring structures (type 2). All images are at x1,000 magnification. (B) Schematic representation of how the AChR-positive and total NMJ areas were defined, using the freehand tool in Image J image analysis software. The AChR-positive area was taken to be that area stained with ${alpha}$ -bungarotoxin (btx) at the terminus of the synaptic nerve. The total NMJ area was taken to encompass the entire AChR-positive area, leaving no internal space between the outermost branches. (C) Quantified synaptic areas occupied by AChRs, total NMJ areas (expressed in arbitrary units ± standard errors of the mean), and percentage of the area occupied by AChRs of NMJs of 3-month-old homozygous floxed (+/+) and homozygous Gabp ${alpha}$ skeletal-muscle-specific knockout (–/–) mice. *, P < 0.05 (Student's two-tailed t test). Types 1 and 2 are the two morphological types of NMJs observed in Gabp ${alpha}$ mutant animals at a frequency of 76% and 24%, respectively.

AChR-positive areas, as determined by ${alpha}$ -bungarotoxin staining,were quantified for both type 1 and type 2 mutant NMJs and thenexpressed as percentages of the total NMJ area (Fig. 4B). Type1 knockout NMJs of the soleus muscle were significantly increasedin both the area occupied by AChRs and the total area of theNMJ (P = 0.0008 and P = 0.0024; n = 81; Student two-tailed ttest) (Fig. 4C, center column). However, the percentage of thearea occupied by AChRs was unchanged relative to the controls.By contrast, type 2 knockout NMJs were of equal area relativeto control mice yet showed a significant decrease in the percentageof the area occupied by AChRs (P = 0.034; n = 26; Student two-tailedt test) (Fig. 4D, right column). The increased area occupiedby AChRs observed in 76% of Gabp ${alpha}$ mutant NMJs (type 1 morphology)corresponded to an observed 1.8-fold increase in the numberof AChRs found in the synaptic region of ¹²⁵I-labeled ${alpha}$ -bungarotoxin-stainedsoleus muscles from 3-month-old Gabp ${alpha}$ knockout mice in comparisonto control littermates (12,559 versus 6,939 counts; P = 0.013;n = 9) (see Fig. S3 in the supplemental material).

No difference in the distributions and appearance of mitochondria,synaptic vesicles, or postsynaptic junctional folds was detectedat the NMJs of 3-month-old Gabp ${alpha}$ skeletal-muscle-specific knockoutmice and homozygous floxed controls, as determined by electronmicroscopic examination of soleus and diaphragm muscles (datanot shown).

Neuromuscular spontaneous and evoked transmitter release is reduced in Gabp ${alpha}$ mutant mice. Given the alterations in morphology and number of postsynapticAChRs of NMJs from Gabp ${alpha}$ skeletal-muscle-specific knockout mice,we examined NMJ physiology in these mice. We measured evokedEPCs, MEPCs, and the NTI at NMJs of diaphragm and soleus musclesfrom Gabp ${alpha}$ mutant and homozygous floxed littermate control miceat 3 months of age. These parameters were used to calculatethe mean quantal content, a measure of the average evoked releaseof acetylcholine from motor nerve terminals. The NTI was recordedin every extracellular recording, although EPCs were highlyintermittent in both knockout and control NMJs and no intermittencein the NTI was observed throughout the recordings (Fig. 5A and E).This suggested that the decrease in the evoked transmitter releaseand associated increased failure rate of stimuli to evoke transmitterrelease in Gabp ${alpha}$ mutant terminals were not due to failure ofthe action potential to invade the nerve terminal (Fig. 5) butrather a failure of depolarization-secretion coupling.

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FIG. 5. Extracellular recordings from NMJs of homozygous floxed control (A to D) and Gabp ${alpha}$ conditional knockout mice (E to H). Panels A and E show examples of evoked EPCs. Panels B and F show examples of MEPCs. In panels A, B, E, and F, five consecutive traces are superimposed. Note the invariable presence of the NTI in both control (A) and mutant (E) recordings. Frequency amplitude histograms of MEPCs (C and G) and evoked (D and H) amplitudes are shown. The histograms shown in panels C and D were constructed from a single recording site, as were the histograms shown in panels G and H. The distributions of MEPC amplitudes were similar in both control and Gabp ${alpha}$ conditional-knockout mice. EPCs were skewed toward higher amplitudes in control mice, and the number of failures (black bars) was higher at NMJs from Gabp ${alpha}$ mutant mice (H) compared to controls (D). (I) Comparison of biophysical properties of 3-month-old homozygous floxed Gabp ${alpha}$ control (+/+) and Gabp ${alpha}$ conditional-knockout (–/–) mice. *, P < 0.05; **, P < 0.01; ***, P < 0.001 (Student's two-tailed t tests). (J) Representation of MEPC decay rate constants from NMJs of Gabp ${alpha}$ conditional-knockout (hatched bars) and homozygous floxed (black bars) mice. The histograms were constructed from a single recording site taken from either mutant or control soleus muscle. The decay rate constants for control MEPCs varied from 10 ms to 35 ms. In contrast, the decay rate for Gabp ${alpha}$ mutant mice varied from 10 ms to 130 ms. This resulted in a significantly longer mean in decay rates at NMJs of Gabp ${alpha}$ conditional-knockout mice than in control animals.

The amplitudes of both the MEPCs and EPCs were significantlyreduced at soleus NMJs from Gabp ${alpha}$ knockout mice compared to controlmice (Fig. 5I). The mean amplitudes for MEPCs were 171.15 ±25.98 µV for knockout mice and 277.44 ± 32.41 µVfor controls (P = 0.018; n = 12; Student's paired t test). Furthermore,the mean EPC amplitudes appeared to be no greater than MEPCmean amplitudes at NMJs from Gabp ${alpha}$ knockout NMJs (167.16 ±15.08 µV) (Fig. 5I). By constructing amplitude frequencyhistograms of MEPCs and EPCs, we were able to estimate quantalcontents. The quantal content was significantly lower in themutant nerve terminals from soleus and diaphragm muscles (Fig.5I). These results indicated that both presynaptic and postsynapticabnormalities had occurred at NMJs from Gabp ${alpha}$ conditional-knockoutmice, culminating in the observed drop in the mean quantal content.

NMJ decay constants are significantly longer in Gabp ${alpha}$ mutant mice. Gabp is a key member of the ARIA/Heregulin/Neuregulin-ErbB signaltransduction pathway (17). This pathway drives expression ofthe postsynaptic AChR ${varepsilon}$ subunit gene, thus triggering the changeof composition of AChRs from fetal ( ${alpha}$ ß₂ ${delta}$ ${gamma}$ ) to adult ( ${alpha}$ ß₂ ${delta}$ ${varepsilon}$ )by the end of postnatal week 1, allowing longer AChR channelopening times when ACh binds to its receptor. We therefore examinedthe decay constants (a measure of the channel opening time)at soleus and diaphragm NMJs from 3-month-old Gabp ${alpha}$ skeletal-muscle-specificknockout and homozygous floxed littermate control mice and observedthat the decay constants at NMJs from Gabp ${alpha}$ mutant mice weresignificantly longer than those of control mice (Fig. 5I and J).The mean decay constant of MEPCs for Gabp ${alpha}$ mutant soleus NMJswas 8.27 ± 2.25 ms, compared to 2.83 ± 0.33 msfor control NMJs (P = 0.026; n = 12; Student's paired t test).Similar differences were observed for diaphragm Gabp ${alpha}$ knockoutNMJs (Fig. 5I). Frequency histograms from individual recordingsites typically showed a highly positive skew of the decay constantsranging out to 100 to 150 ms in duration at soleus and diaphragmGabp ${alpha}$ mutant NMJs compared to 30 to 40 ms for control NMJs (Fig.5J). The increase in the MEPC decay constant is consistent witha failure to express sufficient levels of AChR ${varepsilon}$ , a likely consequenceof Gabp ${alpha}$ gene inactivation in skeletal muscles of Gabp ${alpha}$ mutantmice.

The alterations in electrophysiology of Gabp ${alpha}$ mutant NMJs didnot, however, result in any significant change in skeletal musclefatigability (at 1 year of age) or in strength (from 1 to 6months of age), as determined by rotarod and wire grip tests,respectively (data not shown).

Altered AChR expression levels in skeletal muscle of Gabp ${alpha}$ mutant mice. In order to explain the underlying cause of changes in NMJ structureand function in Gabp ${alpha}$ mutant mice, we examined the expressionlevels of Gabp target genes. Individual diaphragm muscles fromfour floxed mice and four homozygous mutant mice at 3 monthsof age were studied, using real-time RT-PCR to quantify thelevels of AChR ${delta}$ , AChR ${varepsilon}$ , and Utrophin (Fig. 6A). AChR ${varepsilon}$ expressionwas decreased 10-fold (P = 0.0000013; n = 12; Student two-tailedt test) in Gabp ${alpha}$ mutant diaphragms. Although the mean expressionlevel of AChR ${delta}$ was 50% of normal in mutant diaphragms, the highdegree of variability between floxed animals of mixed-strainbackground obscured the statistical significance of these data.Interestingly, analysis of cDNA from soleus muscles of the sameanimals showed no significant difference between genotypes (datanot shown). However, a large decrease in the mean expressionlevel of AChR ${delta}$ was again masked by a large variation in floxedcontrols. Utrophin levels were unaltered in skeletal muscleof Gabp ${alpha}$ knockout mice compared to their floxed littermates (Fig.6A), suggesting Gabp ${alpha}$ is not required for transcriptional activationof Utrophin, at least in these tissues, and immunostaining ofsoleus muscle fibers showed no change in utrophin protein expressionbetween genotypes (data not shown).

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FIG. 6. Expression of Gabp target genes in Gabp ${alpha}$ conditional-knockout mice. (A) Real-time RT-PCR analysis of transcript levels of Gabp target genes, using cDNA from diaphragm muscles of four 3-month-old homozygous floxed (+/+) and homozygous Gabp ${alpha}$ skeletal muscle-specific knockout (–/–) mice. The expression levels of each transcript are expressed as a ratio to ß-actin. The ratios were adjusted so those of floxed mice were 1. The error bars represent standard errors of the mean. *****, P < 0.000005; n = 12 (two-tailed Student's t test). Levels of Rapsyn were measured as a negative control, as it is not a Gabp gene target. (B) Immunostaining of transverse cryosections from 3-month-old homozygous floxed (+/+) and Gabp ${alpha}$ skeletal-muscle-specific knockout (–/–) mice with Texas red-conjugated ${alpha}$ -bungarotoxin (btx) and antibodies recognizing AChR ${delta}$ or AChR ${gamma}$ showing colocalization and increased expression of AChR ${gamma}$ in Gabp ${alpha}$ mutant mice. The images were taken at x400 magnification.

These real-time RT-PCR data do, however, validate AChR subunitsas target genes regulated by Gabp. Furthermore, immunostainingof medial gastrocnemius tissue sections from 3-month-old micewith antibodies specific for AChR ${delta}$ and AChR ${gamma}$ expression (SantaCruz Biotechnology, Santa Cruz, CA) confirmed that expressionof AChR ${delta}$ protein was unchanged in the Gabp ${alpha}$ mutant compared tohomozygous floxed controls (Fig. 6B). However, protein levelsof AChR ${gamma}$ were upregulated in the Gabp ${alpha}$ skeletal-muscle-specificknockout animal (Fig. 6B). The fetal AChR ${gamma}$ subunit is normallyreplaced by the adult AChR ${varepsilon}$ subunit within the first two postnatalweeks in mice (29), resulting in a change in ion channel properties.This increase in AChR ${gamma}$ protein expression correlates well withthe observed decrease in AChR ${varepsilon}$ transcript levels and explainsthe increased decay constants of MEPCs of Gabp ${alpha}$ mutant mice comparedto those of littermate controls. AChR expression may also beregulated by the basic helix-loop-helix factors myogenin andMyoD. However, we did not observe an up-regulation of theseproteins (data not shown), indicating that altered expressionof AChR subunits is due directly to loss of Gabp ${alpha}$ expression.

DISCUSSION

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DISCUSSION

We generated Gabp ${alpha}$ skeletal-muscle-specific knockout mice thatdemonstrated reduced levels of the target gene AChR ${varepsilon}$ in the diaphragm,altered distribution of AChRs at the NMJ, and abnormal neurotransmissionproperties, resulting from a compensatory increase in AChR ${gamma}$ expression.This model demonstrates an important role for Gabp ${alpha}$ in the structureand function of neuromuscular synapses.

We showed that expression of the Gabp target gene AChR ${varepsilon}$ is decreasedin the diaphragms of Gabp ${alpha}$ knockout mice. A trend toward reducedmRNA levels of AChR ${delta}$ was observed, and no change in Utrophinexpression levels was apparent. This indicates that other transcriptionfactors, including other ETS proteins, expressed in skeletalmuscle cells may, to some degree, compensate for loss of Gabp ${alpha}$ expression. This is supported by reduced levels of Utrophin,AChR ${varepsilon}$ , and AChE in the vastus lateralis of mice expressing adominant-negative ETS (comprised of the ETS DNA binding domain)protein in skeletal muscle (7). In addition, although our datashowing decreased AChR ${varepsilon}$ expression in the absence of Gabp functionagree with those of Briguet and Ruegg (1), an impairment inAChR clustering was also observed following in vivo injectionof a Gabpß dominant-negative construct into rat soleusmuscle fibers (1), suggesting that the milder phenotype observedin this study may be partly explained by the ability of Gabpßto partner with another transcription factor. Interestingly,expression of a dominant-negative ETS protein results in transgenicmice with an altered AChR morphology at the NMJ (7). These dataclearly imply a role of skeletal-muscle-expressed ETS factorsin NMJ function, and the findings are strikingly similar, althoughmore severe, than those described here for Gabp ${alpha}$ skeletal muscleknockout mice.

The physiological effect of loss of Gabp ${alpha}$ expression upon neuromusculartransmission resembles that of mice lacking the ErbB2 and ErbB4neuregulin receptors in skeletal muscle (15). Like skeletal-muscle-specificGabp ${alpha}$ knockout mice, adult mice lacking neuregulin signalingspecifically in skeletal muscle have decreased MEPC amplitudesand low MEPC decay rates (15). This further validates Gabp asa key effecter of the neuregulin-ErbB signaling pathway andemphasizes a specific function of Gabp at the NMJ that cannotbe compensated for by other proteins.

Previous mutation studies have identified the N-box (ETS site)as a critical element for synapse-specific expression of bothAChR ${delta}$ (18, 23) and - ${varepsilon}$ (10). While we have shown decreased AChR ${varepsilon}$ gene expression, this drop had no effect upon postsynaptic localizationand clustering of AChRs in muscles of Gabp ${alpha}$ skeletal-muscle-specificknockout mice, suggesting that Gabp ${alpha}$ is not essential for theformation of postsynaptic AChRs. However, loss of Gabp ${alpha}$ expressiondoes result in altered NMJ morphology in knockout muscles. Inagreement with the phenotype of mice expressing a dominant-negativeETS protein in skeletal muscle (7), we observed that type 2NMJs of Gabp ${alpha}$ ^–/– soleus muscles showed a single ringstructure and a significant decrease in the percentage of thearea occupied by AChRs, with the remaining type 1 NMJs showingless branching than those of homozygous floxed Gabp ${alpha}$ controls.

Type 1 NMJs of Gabp ${alpha}$ conditional-knockout mice had an increasedarea compared to those of wild-type mice, but the percentageof the area occupied by AChRs remained unchanged. This correspondsto the observed increase in the total number of AChRs foundin the synaptic region of soleus muscle tissues from Gabp ${alpha}$ conditional-knockoutmice. The increase in AChR protein expression in Gabp ${alpha}$ mutantmice may be a secondary effect of loss of Gabp ${alpha}$ expression ifthe muscle is responding to ineffective innervation. In addition,the multinucleated nature of skeletal muscle cells means thatvariable Cre splicing efficiency of Gabp ${alpha}$ in myonuclei alonga muscle fiber may result in altered neuromuscular transmissionwithout resulting in an overall decrease in AChR protein expression.

Together with the lower MEPC and EPC mean amplitudes at Gabp ${alpha}$ mutant soleus NMJs, these data suggest that although compensatorymechanisms may allow AChR protein expression at the NMJ in theabsence of Gabp ${alpha}$ , altered distribution of these receptor moleculeswithin an NMJ results in impaired neuromuscular signaling. Specifically,we observed reduced EPC and MEPC amplitudes, leading to a 50%drop in the mean quantal content in NMJs of Gabp ${alpha}$ mutant mice.The longer decay times of EPCs at NMJs of the Gabp ${alpha}$ mutant animalsis explained by the observed upregulation of AChR ${gamma}$ expressionin an attempt to compensate for the loss of the AChR ${varepsilon}$ proteinat the NMJs of conditional-knockout mice. Upregulation of AChR ${gamma}$ expression has been observed in mice lacking AChR ${varepsilon}$ (43) and somehumans suffering from CMS (12), resulting in an increase inthe channel opening time (and current decay time) and a decreasein the amplitude of endplate potentials. However, the high safetyfactor of neurotransmission in mice (26), together with theincreased total number of AChRs observed in synaptic regionsof soleus muscles lacking Gabp ${alpha}$ expression, suggests that sufficientAChR ${varepsilon}$ protein is made in the absence of Gabp ${alpha}$ expression to allowovertly normal skeletal muscle function. The high safety factoris clearly demonstrated by mice lacking the neuromuscular structuralprotein utrophin, which are healthy and show no signs of muscleweakness despite postsynaptic abnormalities, such as low numbersof AChRs and fewer junctional folds (6).

It would be of interest in the future to study mice of up to2 years of age for any signs of deterioration, as the human ${alpha}$ -skeletal actin gene promoter used to drive Cre expression inthis study was previously shown to allow high levels of regenerationof muscle fibers through residual gene expression in satellitecells (31). However, no histological signs of such compensationwere visible up to 6 months of age, and preliminary rotarodand grip analyses of Gabp ${alpha}$ mutant mice up to 1 year old showedno loss of coordination, balance, or muscle strength. Studiesare also under way to better understand the in vivo role ofGabp ${alpha}$ in the regulation of nuclear encoded genes of mitochondrialfunction, such as subunits of cytochrome c oxidase. Early embryoniclethality of complete Gabp ${alpha}$ knockout mice (35), and our preliminaryresults showing decreased levels of mitochondrial transcriptionfactor A and altered fiber type proportions in Gabp ${alpha}$ skeletal-muscle-specificmutants (data not shown), support the idea put forth in numerousin vitro studies; Gabp ${alpha}$ (also known as nuclear respiratory factor2) is a key regulator of cellular metabolism (38).

The loss of Gabp ${alpha}$ expression in skeletal muscle results in irregularNMJ morphology and decreased EPC amplitude, mean quantal content,and decay time, indicating that the Gabp complex is necessaryfor the development of functional NMJs within skeletal musclefibers. Interestingly, disruption of Gabp function by mutationof the N box of the target gene AChR ${varepsilon}$ results in postsynapticmuscular disease. Therefore, disruption of Gabp ${alpha}$ expression couldbe an underlying cause of human diseases, such as CMS.

ACKNOWLEDGMENTS

We are very grateful to the Monash Medical Centre animal housestaff, E. De Luca, S. Tsao, D. Finkelstein, I. Harper, T. Wilson,and L. Mittaz Crettol for their technical assistance and helpfulcomments throughout this work. We thank Judith Melki and EdnaHardeman for providing the h ${alpha}$ SA-Cre mouse line, Klaus Rajewskyfor kindly providing the floxed pMCI-Neomycin cassette, SteveBurden for providing Gabp ${alpha}$ -specific antisera, and Michael Liangfor technical support.

This work was supported by grants from the Australian NationalHealth and Medical Research Council (S.R., P.G.N., and P.J.H.).

FOOTNOTES

* Corresponding author. Mailing address: Monash Institute of Medical Research, Monash Medical Centre, 246 Clayton Road, Clayton, Victoria 3168, Australia. Phone: 61 3 9594 7236. Fax: 61 3 9594 7211. E-mail: Paul.Hertzog{at}med.monash.edu.au

Published ahead of print on 26 February 2007.

Supplemental material for this article may be found at http://mcb.asm.org.

Present address: Genomics Institute of the Novartis ResearchFoundation, 10675 John Jay Hopkins Drive, San Diego, CA 92121.

Present address: Merck Research Laboratories, Merck & Co.,126 East Lincoln Avenue, Rahway, NJ 07065.

REFERENCES

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