The Mouse Dystrophin Enhancer Is Regulated by MyoD, E-box-binding Factors, and by the Serum Response Factor*

Philip Marshall, Nathalie Chartrand, and Ronald G. WortonDagger

From the Ottawa Hospital Research Institute, Ottawa, Ontario K1H 8L6, Canada

Received for publication, March 8, 2001

    ABSTRACT
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES

In vivo studies in the mouse have revealed that the muscle promoter of the mouse dystrophin gene can target the right ventricle of the heart only, suggesting the need for other regulatory elements to target the skeletal muscle as well as other compartments of the heart. In this study we report the identification of the mouse dystrophin gene enhancer that is located ~8.5 kilobases downstream from the mouse dystrophin gene muscle promoter. The enhancer was tested in myogenic G8, H9-C2, and nonmyogenic 3T3 cell lines and is mostly active in G8 myotubes. Sequence analysis of the mouse dystrophin gene enhancer revealed the presence of four E-boxes numbered E1-E4, a putative mef-2 binding site, and a serum response element. Site-directed mutagenesis studies have shown that E-boxes 1, 2, and 3 as well as the serum response element are required for enhancer activity. Gel shift analysis revealed two binding activities at binding sites E1 and E3 which were specific to myotubes, and supershift assays confirmed that myoD binds at both these sites. Our study also shows that werum response factor binds the serum response element but in myoblasts and fibroblasts only, suggesting that serum response factor may repress enhancer function.

    INTRODUCTION
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES

The 2.5-megabase gene encoding the cytoskeletal protein, dystrophin (1, 2) is the largest gene yet identified and is complex with a minimum of seven promoters. Three promoters, muscle (3), brain (4), and Purkinje (5), express full-length dystrophin isoforms that localize in the skeletal/cardiac muscle, the cerebral cortex, and in cerebellar Purkinje cells, respectively. Four other promoters located in introns 29, 55, 59, and 68 encode shorter isoforms Dp 260 (6), Dp 140 (7), Dp 116 (8), and Dp 71 (9, 10), which are expressed in retina, the central nervous system, the peripheral nervous system, and non-muscle tissues, respectively. The exact role of dystrophin has yet to be determined, but many studies suggest that in muscle it maintains the cytoarchitecture of the cell by bridging intracellular F-actin filaments to the extracellular matrix via contacts with the dystroglycan complex (11, 12). What is known is that mutation in the gene resulting in loss of dystrophin is the major cause of Duchenne muscular dystrophy, whereas mutations that alter or reduce the amount of the protein generally cause the milder Becker muscular dystrophy.

Although many mutations in the dystrophin gene affect coding sequences, a few of the known mutations affect non-coding sequences, and often these impact on transcription of the gene. This type of mutation is not frequently observed in Duchenne muscular dystrophy or Becker muscular dystrophy but is more common in a group of X-linked dilated cardiomyopathy patients (13), in which promoter deletions (14) or splice site mutations (15) abolish expression of the muscle isoform of dystrophin in skeletal and cardiac muscle. These individuals continue to express full-length dystrophin in their skeletal muscle from the brain and/or Purkinje promoters (15, 16), normally silent in this tissue. This suggests that different regulatory elements are involved in regulation of dystrophin gene expression in skeletal and cardiac muscle. This conclusion is supported in mouse by in vivo studies showing that the muscle core promoter of the mouse dystrophin gene is capable of expressing a reporter gene only in the right ventricle of the heart (17), suggesting that other other cis-acting elements are required for expression in other compartments of the heart and in skeletal muscle.

The intron-1 enhancer described previously in intron-1 of the human gene is a good candidate for this regulatory function. Because detailed regulatory studies of the dystrophin gene cannot be done in human, we have turned to the mouse gene and have mapped an intron-1 enhancer element located 8.5 kilobases (kb)1 downstream from the mouse dystrophin muscle promoter which shows 65% homology with its human counterpart located 6.5 kb downstream (18) from the human dystrophin muscle promoter. We have characterized the mouse enhancer in G8 and H9-C2 myogenic and 3T3 non-myogenic cell lines and found that enhancer activity is specific to differentiating myoblasts. Deletion and site-directed mutagenesis studies have confined the enhancer activity to a minimum of four putative binding sites. These include three E-boxes, E1-E3, and a serum response element (SRE). E1 and E3 match the consensus 5'-AACAc/g c/g TGC a/t while E2 and a sequence contained in the SRE resemble the consensus 5'-GGa/cCANGTGGc/gNa/g. Factor binding studies by mobility shift analysis suggest that ubiquitous factors bind E2 and the SRE whereas myotube-specific factors complexed with myoD bind E1 and E3.

    EXPERIMENTAL PROCEDURES
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES

Isolation of the Mouse Dystrophin Muscle Promoter and the Mouse Dystrophin Enhancer (MDE)-- A bacterial artificial chromosome (BAC) (20) insert that contains the mouse dystrophin muscle promoter was identified by screening a BAC genomic library (Genomic Systems Inc.) with a probe that extends from position -500 to -900 relative to the transcriptional start site of the mouse dystrophin muscle promoter. To map the promoter within the BAC clone, the BAC insert was digested with EcoRI, BamHI, or HindIII restriction endonuclease, and fragments were separated by agarose gel electrophoresis, transferred to a GeneScreen Plus membrane (NEN Life Science Products). This was hybridized to the same probe in the presence of 6 × sodium citrate, 5 × Denhardt's, 0.5% SDS, 10% dextran sulfate, and 100 µg/ml herring sperm at 65 °C for 20 h. The membranes were washed in 1 × sodium citrate, 0.1% SDS at 65 °C for 20 min following a wash at room temperature. A positive EcoRI fragment of 7.0 kb was subcloned into pBluescript SK+ (pmdp) and mapped by partial cleavage using EcoRI, BamHI, and HindIII restriction endonucleases (Fig. 1A).


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Fig. 1.   Mapping the region that encompasses the mouse dystrophin promoter and enhancer. Panel A, three fragments were subcloned into pBluescript SK+ to yield subclones pmdp, pmdeH, and pmdeB. Inserts were mapped by partial cleavage with EcoRI (E), HindIII (H), and BamHI (B) restriction endonucleases and aligned to generate a contig of 20 kb. The first exon (EX1) of the muscle isoform of the mouse dystrophin gene is located ~8.5 kb upstream of the MDE (MDE). Panel B, a 3-kb fragment (plain line) that contains the enhancer was subcloned from pmdeB into the EcoRI site of the pBluescript SK+ (bold line) (see "Experimental Procedures") to generate the pmdeE recombinant plasmid. The positions of the SacI (S) and XhoI (X) restriction sites and the T7 promoter (T7) are as indicated. 0.5- and 0.28-kb fragments that include the MDE were amplified by PCR and tested for enhancer activity as described in Fig. 2.

To identify restriction fragments that include the mouse counterpart to the human enhancer, the BAC clone was incubated with restriction endonucleases EcoRI, BamHI, and HindIII. Restriction fragments were separated by agarose gel electrophoresis and transferred to a GeneScreen Plus membrane. The latter was hybridized to a SpeI-SacI 195-base pair (bp) fragment that includes the human dystrophin intron-1 enhancer in the presence of 6 × sodium citrate, 5 × Denhardt's, 0.5% SDS, 10% dextran sulfate, and 100 µg/ml herring sperm at 50 °C for 20 h. Subsequently the membranes were washed in 6 × sodium citrate, 0.1% SDS at 50 °C for 20 min following a wash at room temperature. Positive fragments include a HindIII fragment of 7.0 kb and a BamHI fragment of 11 kb which were subcloned into pBluescript SK+ to generate pmdeH and pmdeB, respectively (Fig. 1A). Both fragments were mapped by partial cleavage using EcoRI, BamHI, and HindIII restriction endonucleases, and a 3.0-kb EcoRI that hybridized to the human dystrophin enhancer was subcloned from pmdeB into the EcoRI site of pBluescript SK+ to generate pmdeE (Fig. 1B).

Luciferase Constructs-- Recombinant plasmids that were used to characterize the dystrophin muscle enhancer activity are derived from the pGL3 vector series containing the firefly luciferase gene (Promega). The C3 construct (Fig. 2) was made by inserting a 3.0-kb SacI-XhoI fragment that was isolated from pmdeE between the SacI and XhoI sites of the pGL3-P vector (Promega) upstream of the SV40 early promoter and the luciferase gene. To generate the constructs C1 and C2, a 3.0-kb BamHI fragment that was isolated from pmdeE and contains the MDE was inserted in either orientation at the BamHI site of the pGL3-P vector.


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Fig. 2.   Activation of the SV40 early promoter by the MDE in myogenic and non-myogenic cell lines. Fragments of 3, 0.5, and 0.28 kb which contain the MDE were positioned either upstream of the early SV40 promoter (SV40) or downstream the SV40 polyadenylation signal (PA) of the firefly luciferase reporter gene. The luciferase activity was measured in G8 myotubes (G8 mt), G8 myoblasts (G8 mb), H9 C2 myotubes (H9 mt), H9-C2 myoblasts (H9 mb), and 3T3 fibroblasts. Transcription activation was determined by comparing the activity of each construct with the activity of a construct that expresses the luciferase gene from the early SV40 promoter. The values obtained are expressed as the means ± S.E., and those higher than 2.5 are boxed. Experiments were performed in triplicate between two and six times.

In constructs of the A series, a fragment of 500 bp was tested for enhancer activity. In A1 and A2, the 500-bp fragment was amplified by polymerase chain reaction (PCR) using oligonucleotide primers 5'-ATCGTAACGCGTGTCTGACTTCTCAGTTCAGACTTTCACCTTGG and 5'-ATCGTAACGCGTATAACACTTGATGCGTGCTGAAATG, which contain the MluI restriction site (underlined). In A3 and A4, the 500-bp fragment was amplified using oligonucleotide primers 5'-ATCGTAGGATCCGTCTGACTTCTCAGTTCAGACTTTCACCTTGG and 5'-ATCGTAGGATCCATAACACTTGATGCGTGCTGAAATG, which contain a BamHI restriction site. PCR products were gel purified using QIAQUICK gel extraction cartridges (Qiagen Inc.) and subsequently cleaved with either MluI or BamHI. MluI fragments were inserted at the MluI site of pGL3-P uspstream of the of the SV40 promoter to generate A1 and A2. BamHI fragments were inserted at the BamHI site of pGL3-P downstream from the luciferase gene to generate A3 and A4.

The constructs B1 and B2 were made by deleting 220 bp from the MDE contained in constructs A1 and A2. Thus oligonucleotide primers that define the deletion end points 5'-ATCGTAGAATTCCTTTCCAAGGTGAAAGTCTGAACTGAG and 5'-ATCGTAGAATTCAAGTGAACGAAGACAAAATGTGACC and contain an EcoRI restriction site (underlined) were used to amplify a DNA fragment of 5.2 kb which is missing 220 bp of the 500 enhancer sequencer. Subsequently the fragment was cleaved with EcoRI, self-ligated, and transformed into Max Efficiency Escherichia coli DH5alpha (Life Technologies Inc.). Deletions of the enhancer sequences were confirmed by sequence analysis with an automatic Applied Biosystems 373 sequencer.

Site-directed Mutagenesis of Enhancer Protein Binding Sites-- Binding determinants within the putative protein binding sites of the MDE were replaced with restriction sites by PCR. The oligonucleotide primers that were used to introduce base changes in the MDE binding sites E1-E4, mef-2, and SRE are listed in Table I. As a result, the bindings sites E1-E4 were replaced by a BamHI restriction site, whereas the mef-2 binding site and the SRE were replaced by MluI and PstI restriction sites, respectively. The template used was the B1 construct in which the BamHI site was destroyed by filling in the cohesive ends with Klenow DNA polymerase (New England Biolabs Inc.). The PCR products that encode mutations in E-boxes E1-E4 were cleaved with BamHI, and products encoding mutations of the putative mef-2 and SRE binding sites were cleaved with MluI and PstI. Cleaved DNA products were gel purified using QIAQUICK cartridges, self-ligated using T4 DNA ligase (New England Biolabs Inc.), and transformed into E. coli DH5alpha . All mutations that were introduced in the MDE were confirmed by sequence analysis.

                              
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Table I
Oligonucleotide primers used to mutagenize putative binding sites of mouse dystrophin enhancer
The putative binding sites E1-E4 were disrupted by the insertion of a BamHI site (bold), and the mef-2 and SRE were disrupted by the insertion of an MluI site (bold).

Transfections and Biochemical Assays-- For liposome-mediated transfections, 5 µg of recombinant plasmid and 2 µg of pGK beta -galactosidase were incubated with .0014 M DODAC:DOPE liposomes (Inex Pharmaceuticals Inc.) in 0.9% NaCl at room temperature for 10 min in a final volume of 50 µl. 750 µl of alpha -minimal Eagle's medium and 25% fetal bovine serum was added, and the mix was added to ~2 × 105 cells on the surface of a well (six-well dish). Cells were incubated with the transfection mix for 3 h at 37 °C, 5% CO2. The mix was removed, and alpha -minimal Eagle's medium containing 10% fetal bovine serum, 10% horse serum was added, and the cells were incubated at 37 °C, 5% CO2 for 20 h. Luciferase activity was measured in both myoblasts and myotubes. Myoblasts were harvested after 24 h with a cell scraper in luciferase lysis buffer (25 mM Tris phosphate, pH 7.8, 2 mM DTT, 2 mM CDTA, 10% glycerol, 1% Triton X-100). Alternatively, cells were induced to differentiate into mature myotubes in alpha -minimal Eagle's medium containing 1% horse serum over 4 days and were harvested as above. Fibroblasts were harvested 1 day after transfection and harvested as above. Cellular extracts were prepared as described by the manufacturer (Roche).

Luciferase activity was measured in a 5-µl aliquot of cellular extract mixed with 100 µl of luciferin reagent (20 mM Tricine, 1 mM (MgCO2)4 Mg(OH)2.5H2O, 2.7 mM MgSO4.7H2O, 0.1 mM EDTA, 33.3 mM DTT, 270 µM coenzyme A, 470 µM luciferin, 530 µM ATP) using a ECG Berthold Lumat 9700 luminometer. The protein concentration of the cellular extracts was determined with the Bio-Rad protein assay kit. beta -Galactosidase activity was determined by diluting 10-30 µl of the extract in luciferase lysis buffer in a final volume of 150 µl. The diluted extract was then mixed with 150 µl of 2 × beta -galactosidase buffer (200 mM sodium phosphate, pH 7.3, 2 mM MgCl2, 100 mM beta -mercaptoethanol, 1.33 mg/ml o-nitrophenyl beta -D-galactopyranoside). The luciferase activity of each extract was normalized for protein concentration and beta -galactosidase. The luciferase activity obtained from constructs that contain the SV40 promoter/dystrophin enhancer was expressed relative to the activity obtained from constructs that express the luciferase gene from the SV40 promoter.

Nuclear Extracts and Gel Mobility Shift Assays-- Nuclear extracts from all cell lines were prepared as follows. Cells from a 10-cm dish were washed twice with 3 ml of phosphate-buffered saline and harvested by scraping in 500 µl of cold phosphate-buffered saline. Cells were centrifuged at 3,000 rpm at 4 °C for 3 min, resuspended in 400 µl of buffer A (10 mM Hepes, pH 7.8, 1.5 mM MgC12, 10 mM KCI, and l mM DTT). Cytoplasmic membranes were disrupted by passing cells through a 28-gauge needle on a 1-ml insulin syringe ~10 times. Nuclei were centrifuged at 14,000 rpm for 15 s at 4 °C. The supernatant was discarded, and the nuclei pellet was resuspended in 3 volumes of buffer B (20 mM Hepes, pH 7.8, 25% glycerol, 420 mM KCI, 1.5 mM MgC12, 0.2 mM EDTA, 1 mM DTT) containing protease inhibitors (50 ng/ml phenylmethylsulfonyl fluoride, 5 µg/ml aprotinin, 5 µg/ml leupeptin, and 5 µg/ml pepstatin). The nuclei were incubated on ice for a minimum of 20 min and then passed four to eight times through a 28-gauge needle on a 1-ml insulin syringe. The debris was centrifuged at 14,000 rpm for 15 s. The protein concentration of the supernatant was determined using the Bio-Rad protein assay kit, and the supernatant was stored into aliquots at -80 °C.

To generate a binding substrate, 10 pmol of a single stranded oligonucleotide was end labeled at the 5'-end using T4 polynucleotide kinase (New England Biolabs Inc.) and gamma -ATP (Amersham Pharmacia Biotech) in kinase buffer (70 mM Tris-HCI, pH 7.6, 10 mM MgCl2, 5 mM DTT) in a final volume of 10 µl. 10 pmol of the complement strand was prepared in 10 µl of 1 × annealing buffer (10 mM Tris-HCl, pH 7.8, 50 mM NaCl, l mM EDTA) and added to the labeled oligonucleotide. Both strands were heat denatured by boiling for 5 min and allowed to cool slowly at room temperature. Competitor duplexes were generated by heat boiling 500 pmol of complementary strands for 5 min and allowing the strands to cool slowly to room temperature at a final concentration of 1 pmol/µl in 1 × annealing buffer. Binding reactions were carried out on ice for 30 min by incubating 0.05 pmol of labeled oligonucleotide with 1 pmol or 20-fold molar excess of competitor DNA and 3 µg of extract in binding buffer (10 mM Hepes, pH 7.8, 50 mM potassium chloride, 5 mM MgC12, 1 mM EDTA, 5% glycerol). Supershift reactions were carried out by preincubating myoD, E12, or serum response factor (SRF) antibodies (Santa Cruz Biotechnologies Inc.) with the extract for 60 min at 4 °C. The remainder of the binding reaction mix was subsequently added, and binding reactions were carried out as described earlier. Reaction products were loaded on a 6% polyacrylamide 0.5 × TBE gel and run at 4 °C at 150 V.

    RESULTS
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES

Isolating the Mouse Enhancer

Because of the high degree of conservation between mouse and human (19), we hypothesized that a mouse counterpart to the human dystrophin intron-1 enhancer would lie at a similar distance downstream from the mouse promoter. To identify a large mouse clone that might contain the mouse promoter plus exon-1 and intron-1, we screened a mouse BAC genomic library (20) using as probe a DNA fragment containing sequences that extend from -500 to -900 of the mouse dystrophin muscle promoter. A positive clone of ~120 kb was cleaved with EcoRI, HindIII, and BamHI and hybridized to the mouse muscle promoter or the human enhancer (see "Experimental Procedures"). A 7-kb EcoRI fragment that hybridizes with the promoter sequence was subcloned into Bluescript SK+ (Fig. 1A). Two fragments hybridized with the human dystrophin enhancer and therefore contain the putative MDE. A 7-kb HindIII fragment and an 11-kb BamHI fragment that hybridize with the human enhancer were subcloned into pBluescript SK+ to yield pmdeH and pmdeB, respectively (Fig. 1A). All three clones were restriction mapped by partial digestion with EcoRI, BamHI, and HindIII, and the alignment of restriction sites from the three fragments allowed the fine mapping of a contig of ~20 kb (Fig. 1A). According to this restriction map, the putative MDE resides in the region of overlap of clones pmdeH and pmdeB. Digestion of pmdeB with EcoRI resulted in the subclone pmdeE containing this region (Fig. 1B).

Characterization of the Mouse Dystrophin Intron-1 Enhancer

To determine whether the mouse counterpart to the human enhancer could enhance transcription, a 3.0-kb EcoRI fragment (Fig. 1B) that was isolated from pmdeE and contains the putative mouse enhancer was inserted in reverse orientation upstream of the SV40 early promoter and in both orientations downstream from the firefly luciferase reporter gene of the pGL3-P vector series (Promega) to generate recombinant constructs C1, C2, and C3 (Fig. 2). The latter were transfected into mouse skeletal muscle-derived G8 myoblasts (21) as well as into rat heart-derived H9-C2 myoblasts (22) and mouse NIH 3T3 (23) embryonic fibroblasts using DODAC:DOPE liposomes. Myoblasts were harvested after 24 h or induced to differentiate into mature myotubes over 4 days. Fibroblasts were harvested 24 h after transfection. Our results show that in construct C2 and C3 transcription increases by ~11 fold in differentiated G8 myotubes but not in myoblasts (Fig. 2). Interestingly in the C1 construct, transcription from the SV40 promoter increases more than 25- fold. In lines H9-C2 and NIH 3T3 cells, the enhancer has no effect on transcription of the luciferase gene (Fig. 2).

Smaller fragments of 500 and 280 bp (Fig. 1B) which contain the putative MDE were used to generate the constructs of the A and B series, respectively. These were all tested for enhancer activity. Our results show that both the 500- and 280-bp fragment increase transcription by a factor of 5-10-fold in differentiated G8 myotubes and 2-3-fold in differentiated H9-C2 myotubes (Fig. 2). No enhancer activity was observed in G8 or H9-C2 myoblasts or 3T3 fibroblasts (Fig. 2). Our results suggest that sequence elements contained in the 3-kb fragment are required for full enhancer activity and restrict enhancer activity to G8 myotubes. Our results also show quite clearly that sequence elements contained in a shorter fragment of 280 bp contain the minimal elements for enhancer activity.

Identification of Sequences Responsible for Enhancer Activity

Sequence analysis of the MDE revealed a putative mef-2 binding site (24), four E-boxes (25-30) numbered E1-E4, a SRE (31, 32) (Fig. 3A). E-boxes 1 and 3 match the consensus 5'-AACAc/gc/gTGCa/t, whereas E-box 2 matches the consensus 5'-GGa/cCANGTGGc/gNa/g (33). E4 does not appear to match either of these two consensus sequences. Comparison of mouse and human enhancer sequences reveals a 65% homology. The analysis also reveals that the mef-1/mef-2 box (21) of the human enhancer is replaced by a single mef-2 site in the mouse enhancer.


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Fig. 3.   The nucleotide sequence of the MDE. Panel A, the MDE (MOUSE) was aligned with the human dystrophin enhancer (HUMAN). Asterisks (*) show homology between the two sequences. Putative binding sites (boxed) that interact with mef-2 and E-boxes 1-4 (E1-4) were disrupted by the insertion of MluI and BamHI restriction sites, respectively. The boxed sequence that contains the SRE was deleted from the enhancer. Panel B, all enhancer mutations were introduced in a 280-bp fragment using the B1 construct as template and tested for enhancer activity in G8 myotubes as described in Fig. 2.

To determine which of the putative binding sites is required for enhancer activity we replaced the binding sites E1-E4 by a BamHI restriction site and replaced the A-T-rich sequences of the mef-2 site with a MluI restriction site by performing site-directed mutagenesis on the 280-bp enhancer (34). A 27-bp region that contains the SRE was deleted and replaced with a PstI site. The resulting constructs were transfected into G8 myoblasts, and enhancer activity was monitored in differentiated myotubes. Our results show that disruption of E1, E2, E3, and SRE abolishes enhancer activity, whereas disruption of the mef-2 or E4 binding site had no effect on transcription (Fig. 3B). Thus, the MDE requires a minimum of four binding sites to activate transcription in G8 myotubes.

Characterization of the Binding Activities That Define MDE Function

The binding activities at the four putative binding sites were investigated further by gel shift assays (35) using three labeled oligonucleotides that contain E-box 1, E-boxes 2 and 3, or the SRE (Table II). The oligonucleotides that contain each of these sequences were incubated in the presence of nuclear extracts (36) that were prepared from non-myogenic NIH 3T3 fibroblasts, undifferentiated myoblasts, or differentiated myotubes of the G8 myogenic line. The specificity of binding was determined by performing binding reactions in the presence of a series of competitors that were added in 20-fold molar excess relative to the substrate.

                              
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Table II
Oligonucleotides used as top strands of binding substrates E1, 2+3 (E-boxes 2 and 3), and SRE
Binding sites E1, E2, E3, and SRE are in bold.

Binding at E1 of the MDE-- Binding reactions were carried out by incubating a labeled oligonucleotide that contains the E1 site in the presence of G8 myotube, G8 myoblast, or fibroblast extracts. In the presence of myotube extracts three protein-DNA complexes A1, A2, and A3 are apparent (Fig. 4A), whereas in the presence of myoblast and fibroblast extracts only A1 and A3 can be detected (Fig. 4B). A protein-DNA complex that migrates slightly faster than A3 is detected in all of the extracts in the presence every competitor. This suggests that this particular complex is not specific for any of the competitor duplexes used. The lower amounts of A1 in myotubes may come from myoblasts that have not differentiated. Thus, factors in the A1 and A3 complexes are likely to be ubiquitous, whereas certain factors in the A2 protein-DNA complex are likely to be specific to myogenic cells. Because the E1 binding site features an E-box of the mef-1 type, the factors that bind at this site are likely to be part of a mef-1 complex (37, 38). To confirm further that the A2 protein-DNA complex included factors that were specific to an E-box of the mef-1 type, we performed binding reactions in the presence of oligonucleotide competitors that feature E2, E3, mef-2, and the SRE. We notice that A2 is competed out by excess amounts of E3 and E1 competitors. Because both E1 and E3 feature an E-box of the mef-1 type, our results suggest that a mef-1 complex binds to E1.


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Fig. 4.   Binding activities at the E1 binding site. Gel mobility shifts were carried out by incubating a labeled oligonucleotide that contains the E1 binding site with nuclear extracts that were prepared from G8 myotubes (G8 mt; panel A), G8 myoblasts (G8 mb; panel A), and 3T3 cell lines (panel B). The competitors (Table III) are indicated at the top of the gel, and the protein-DNA complexes are indicated on the left. NS designates a nonspecific competitor that contains sequences unrelated to the E1 binding site. In panel C, nuclear extracts from G8 myotubes were preincubated with antibodies to myoD or E12 before being incubated with the labeled oligonucleotide that contains the E1 site.

Because mef-1 complexes are known to include myogenic differentiation factors of the myoD family, we repeated the binding reactions by using E2 competitor in the presence G8 myotube extracts that were preincubated with antibodies to myoD (39) or to E-box-binding factor, E12, which forms heterodimers with myoD (40, 41). The results show that antibodies to myoD block the formation of the protein-DNA complex A2 (Fig. 4C), whereas antibodies to E12 have little or no effect. Because myoD binds to E-boxes by forming heterodimers with E-box-binding factors, our results suggests that myoD heterodimerizes with an E-box-binding factor other than E12.

Binding to the Paired E-boxes, E2 and E3, in the MDE-- Binding reactions aimed at characterizing protein-DNA complexes that occur at E2 and E3 were carried out by incubating a labeled oligonucleotide that contains the two putative binding sites in the presence of G8 myotube, G8 myoblast, and fibroblast extracts. In these experiments four protein-DNA complexes were detected which we have labeled B1, 2, 3, and 4. B1 and B4 appear with all three extracts and are therefore ubiquitous. B3 is specific to myoblasts and 3T3 and may therefore represent a complex that dissociates upon differentiation into myotubes. B2 is specific to myotubes and therefore represents a complex that forms upon differentiation into myotubes.

To determine which of the two E-boxes generated these complexes we carried out binding reactions in the presence of competitors that feature either the E2 or E3 boxes (Table III). Binding reactions were also carried out in the presence of competitors that contain the mef-2 binding site and the SRE of the MDE. The mef-2 binding site differs significantly from the E-box consensus and therefore should not compete for the binding of factors that recognize E2 or E3. The SRE, however, features a sequence that resembles the consensus 5'-GGa/cCANGTGGc/gNa/g shared by the E2 binding site and is therefore expected to compete for the binding of factors that recognize E2.

                              
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Table III
Oligonucleotides used as top strands of competitor duplexes
The NS duplex features 5'- and 3'-ends that remain single stranded (underlined), whereas the other competitors are blunt ended duplexes. The competitors E2 and E3 are identical to the binding substrate 2+3 except for mutations (bold) that were introduced into the E3 or E2 binding sites, respectively.

Protein-DNA complexes B3 and B4 are competed out by oligonucleotide competitors that contain either E2 or E3 (Fig. 5, B and C), whereas B1 complexes are competed out by oligonucleotide competitors that contain E2 and are partially competed by an oligonucleotide containing the SRE (Fig. 5, A-C). Thus, our results suggest that factors in the B1 protein-DNA complex are likely to bind E2 and that factors in the B3 and B4 complexes can bind both E2 and E3. The B2 protein-DNA complex is competed out by the competitors that feature E3, suggesting that factors that compose the B2 complex are likely to bind to E3 (Fig. 5A).


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Fig. 5.   Binding activities at the binding sites E2 and E3. Gel mobility shifts were carried out by incubating a labeled oligonucleotide that contains the E2 and E3 (2+3) binding sites with nuclear extracts that were prepared from G8 myotubes (G8 mt; panel A), G8 myoblasts (G8 mb; panel B), and 3T3 (panel C). The competitors (Table II) that were used in binding reactions are indicated at the top of the gel, and the protein-DNA complexes are indicated on the left. NS is a nonspecific competitor that contains sequences unrelated to the E2 or E3 binding sites. In panel D, nuclear extracts from G8 myotubes were preincubated with myoD or E12 antibodies before being incubated with the labeled oligonucleotide that contains the E2 and E3 binding sites. The competitors (Table III) that were used in the latter reactions are indicated at the top of the gel.

Because B2 complexes can be detected as B1 complexes are competed out by oligonuleotide competitors that include the SRE or E2 binding sites (Fig. 5A), we examined whether the dissociation of B1 complexes is required for the formation of B2 complexes. To this end, labeled oligonucleotides that contain both E2 and E3 were incubated with myotube extracts and increasing amounts of oligonucleotide competitor that contains the E2 site only. The results obtained clearly show that as the amounts of B1 complexes decrease, the amounts of B2 complexes increase (Fig. 6). Therefore, as factors bind E2, E3 is unavailable for binding by other factors. As factors that bind E2 are competed out, however, E3 can interact with factors that yield the B2 protein-DNA complex, indicating that the binding of protein factors to E2 may prevent the binding of protein factors to the E3 binding site.


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Fig. 6.   Competition between E2 and E3 binding activities. Gel mobility shifts were carried out by incubating a labeled oligonucleotide that contains the E2 and E3 (2+3) binding sites with nuclear extracts that were prepared from G8 myotubes (G8 mt). Binding reactions were performed in the presence of a nonspecific competitor (NS) or in the presence of increasing amounts (0.01, 0.05, and 1 pmol) of a competitor that contains the E2 site as indicated at the top.

According to sequence comparisons between the muscle creatine kinase (41) and myosin light chain 1/3 (42) muscle-specific enhancers, the E3 binding site of the MDE matches a consensus 5'-AACAc/gc/gTGCa/t that is recognized by myogenic differentiation factors of the myoD family. Myogenic differentiation factors, however, do not recognize the consensus 5'-Gga/cCANGTGGc/gNa/g shared by the E2 binding site of the MDE. Because B1 and B2 protein-DNA complexes are proposed to occur at binding sites E2 and E3, respectively, the presence of myoD in these complexes was investigated further by supershift analysis. Thus, we carried out two distinct sets of binding reactions in which a labeled oligonucleotide that contains the E2 and E3 binding sites was incubated with G8 myotube extracts in the presence of competitors NS and E2 that yield protein-DNA complexes B1 and B2, respectively. The extracts used were preincubated with antibodies to myoD or to E-box-binding factor, E12, which forms heterodimers with myoD. Our results indicate that B2 but not B1 complexes are blocked by the presence of antibodies to myoD but unaffected by presence of antibodies to E12, suggesting that myoD recognizes the E3 binding site (Fig. 5D). Thus, our results suggest that myoD interacts with the E3 binding site by forming heterodimers with E-box-binding factors other than E12.

Binding to the SRE of the MDE-- Binding reactions that were carried out in the presence of myotube extracts yield a protein-DNA complex C1 (Fig. 7A). Binding reactions that were carried out in the presence of myoblasts and fibroblasts extracts yield complexes C2, C3, C4 (Fig. 7, B and C) and C5, and an additional complex that migrates below C1 is detected in the presence of fibroblasts extracts only. The C1 complex is competed out by the E2 binding site as well as by the SRE. This may be explained by the fact that both the SRE and the E2 binding site resemble the consensus 5'-GGa/cCANGTGGc/gNa/g. Thus, factors that bind the E2 site may also bind the SRE. To determine whether SRF was present in complexes C1-C5, we performed binding reactions by incubating a labeled oligonucleotide that contains the SRE with extracts prepared from myotubes and myoblasts in the presence of SRF antibodies. The results show that SRF antibodies block C5 complexes but do not affect C1-C4 complexes, suggesting that C5 complexes result from SRF interacting with the SRE (Fig. 7D). Protein factors involved in the C1 complex, however, interact with the E2 binding site but not with the antibodies to SRF, indicating that protein factors in the C1 complex may differ from those in the C5 complex. Thus, SRE may interact with E-box-binding factors as well as with SRF. The protein-DNA complexes C2, C3, C4 were not competed out by any of the competitors.


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Fig. 7.   Binding activities at the SRE. Gel mobility shifts were carried out by incubating a labeled oligonucleotide that contains the SRE with nuclear extracts from G8 myotubes (G8 mt; panel A), G8 myoblasts (G8 mb; panel B), and 3T3 (panel C). The competitors (Table III) that were used in binding reactions are indicated at the top, and the protein-DNA complexes are indicated on the left. Nonspecific (NS) competitors contain sequences unrelated to the SRE binding site. In panel D, nuclear extracts prepared from G8 myotubes, myoblasts, and 3T3 were preincubated with SRF antibodies before adding the labeled oligonucleotide that contains the SRE and nonspecific competitor duplex.


    DISCUSSION
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES

Recent studies have shown that the mouse dystrophin muscle promoter targets expression in the right ventricle of the heart only, suggesting that other sequences are needed to target the skeletal muscle and/or other compartments of the heart. Our earlier studies in human have identified an enhancer element downstream from the muscle promoter which was specific to cell lines derived from rat heart. We now report the identification of a MDE that maps in the first intron ~8.5 kb downstream from the muscle promoter of the mouse dystrophin gene. The MDE shows 65% homology with its human counterpart, but the sequence elements that confer enhancer function in both species differ. In human the enhancer is defined by overlapping mef-1/mef-2 binding sites, whereas in the mouse the enhancer is defined by a minimum of four binding sites. These include three E-boxes, two (E1 and E3) of which are of the mef-1 type, and a SRE. A sequence comparison among the mouse dystrophin, the muscle creatine kinase, and myosin light chain-1/3 muscle-specific enhancers reveals that all three feature an E-box that resembles the consensus 5'-AACAc/gc/gTGCa/t paired to an E-box that resembles the consensus 5'-GGa/cCANGTGGc/gNa/g. The conservation of paired E-boxes in the three enhancers suggests that other enhancers that target skeletal and/or cardiac muscle may contain these two sites as well (44).

Transfection experiments show that the MDE increases transcription from the early SV40 promoter mostly in myotubes derived from skeletal muscle. Because the muscle promoter alone targets the expression of lacZ in the right ventricle only, our results suggest that the MDE may be required for targeting expression in skeletal muscle. This hypothesis is strengthened further by observations from our laboratory which show that the MDE can target lacZ expression in both cardiac and skeletal muscle in vivo.2

The protein factors most likely to interact with the sites that confer enhancer activity were characterized further by gel shift analysis. Using myotube extracts, we have identified protein-DNA complexes that occur at the E1 and E3 sites, both of which resemble the mef-1 consensus 5'-AACAc/gc/gTGCa/t. Because myogenic differentiation factors are known to interact with this consensus, we were able to confirm that myoD/myogenin differentiation factors can bind at both these sites. The protein-DNA complex that was detected at the E3 binding site, however, occurs only when factors that bind to the adjacent site, E2, are competed away, suggesting that factors that bind E2 may regulate the binding of factors to E3. Factors that bind E2, however, are not yet known because they bind a consensus 5'-GGa/cCANGTGGc/gNa/g that is not recognized by the known myogenic differentiation factors. Although our study points out the importance of mef-1 type E-boxes for enhancer function, in vivo studies must be carried out to verify this hypothesis.

The SRE may also play a role in regulating enhancer function. In G8 myotubes, the SRE is recognized mostly by E-box-binding factors. In G8 myoblasts, however, the SRE is also recognized by the SRF. The latter is a transcription factor of the MCM1, agamous, deficiens, serum response factor (MADS) box family that regulates gene expression of several muscle-specific genes (45). Because the activity of the MDE is specific to myotubes, E-box-binding factors may act as positive regulators, whereas SRF may act as a negative regulator by preventing the binding of E-box-binding factors to the SRE. Because the latter includes an E-box consensus 5'-GG a/c CANGTGGc/gN a/g which is not recognized by any of the known myogenic differentiation factors, it remains to be determined which E-box-binding factors actually bind the SRE. To this end, previous studies on the muscle creatine kinase enhancer have demonstrated that the methylation protection patterns that occur at this particular sequence are similar but not identical to myoD, confirming that factors do bind at this E-box (33). We are currently investigating the Duchenne muscular dystrophy protection patterns that occur in vivo in order to identify the factors that are most likely to interact with the SRE in both myotubes and myoblasts. (46)

A third factor that may be involved in enhancer function is mef-2. Mef-2 belongs to the family of transcription factors with a MADS box and plays a key role in the regulation of many muscle-specific genes (24, 47). Interestingly, mutations of the mef-2 site in the MDE had no effect on enhancer activity. More surprising is the fact that mef-2 appears to bind the human dystrophin enhancer (48). Although mef-2 acts in combination with myogenic basic helix-loop-helix factors to activate transcription, studies have shown that mef-2 does not require direct binding to DNA (49). Thus, mutations that abolish mef-2 binding to DNA do not necessarily prevent mef-2 from activating transcription. Because mef-2 is frequently associated with functional E-boxes bound by myogenin, we suspect mef-2 may act in combination with transcription factors bound to the E1 or E3 binding sites to activate transcription in skeletal muscle. Because myogenic differentiation factors are absent from the heart, mef-2 may also interact with factors such as SRF (50) or GATA-4 (51) to activate transcription in the cardiac muscle.

Our study also suggests that the genetic environment that surrounds the MDE affect its specificity. Our results show that all of the enhancer fragments that have been tested increase transcription from the SV40 promoter in G8 myotubes. In H9-C2 myotubes, however, the 500-bp enhancer has a moderate effect, whereas the 3-kb or 280-bp enhancers have little or none. This suggests that the 3-kb fragment may contain sequence elements that repress the enhancer function in the H9-C2 line or that the 280-bp fragment may lack sequence elements that enhance transcription from the SV40 promoter. Such elements may include DNA bending motifs or binding sites for proteins that may influence protein-protein interactions via conformational changes in the DNA which affect enhancer and/or promoter activity (52-54). The role of DNA conformation in transcription regulation of muscle-specific genes was demonstrated in studies that showed that the binding of the bHLH factors myoD, Twist, and E2A to their respective sites is mediated by the topology of these sites (55). Another study showed that the proper conformation of a TATA box is required by activator proteins to activate transcription of the myosin heavy chain gene (56). Finally, a third study has reported that transcription activation of the human dystrophin gene depends upon DNA bending of its promoter to activate gene expression (57, 58).

The understanding of how transcription factors control the MDE is likely to shed more light on the mechanisms that regulate transcription of the dystrophin gene in skeletal and cardiac muscle. Such findings may help elucidate complex phenotypes such as those observed in X-linked dilated cardiomyopathy patients who fail to produce dystrophin in the heart but up-regulate the expression of the dystrophin gene in skeletal muscle from Purkinje and brain promoters that are normally silent in skeletal and/or cardiac muscle. The characterization of the MDE is also likely to assist the engineering of therapeutic vectors aimed expressing genes in skeletal and cardiac muscle.

    ACKNOWLEDGEMENTS

We are very grateful to Dr. H. J. Klamut for providing the plasmid SA195 and to Inex Pharmaceuticals Inc. for providing liposomes throughout this study. We thank Drs. David Picketts and Karen Copeland for helpful advice on gel mobility shifts.

    FOOTNOTES

* This work was supported by the Canadian Genetic Diseases Network and the Heart and Stroke Foundation of Canada.The costs of publication of this article were defrayed in part by the payment of page charges. The article must therefore be hereby marked "advertisement" in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.

Dagger To whom correspondence should be addressed: Ottawa Hospital Research Institute, 501 Smyth, Ottawa, Ontario K1H 8L6, Canada. Tel.: 613-737-8802; Fax: 613-737-8803; E-mail: rworton@ohri.ca.

Published, JBC Papers in Press, March 19, 2001, DOI 10.1074/jbc.M102100200

2 Philip Marshall, Nathalle Chartrand, Yves de Repentigny, Rashmi Kothary, Louise Pelletier, and Ronald G. Worton, manuscript in preparation.

    ABBREVIATIONS

The abbreviations used are: kb, kilobase(s); SRE, serum response element; MDE, mouse dystrophin enhancer; BAC, bacterial artificial chromosome; bp, base pair(s); PCR, polymerase chain reaction; DTT, dithiothreitol; CDTA, 1,2-diaminocyclohexane-N,N,N',N'-tetraacetic acid; Tricine, N-[2-hydroxy-1,1-bis(hydroxymethyl)ethyl]glycine; SRF, serum response factor; contig, group of overlapping clones.

    REFERENCES
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES

1. Koenig, M., Hoffman, E. P., Bertelson, C. J., Monaco, A. P., Feener, C., and Kunkel, L. M. (1987) Cell 50, 509-517[Medline] [Order article via Infotrieve]
2. Burghes, A. H. M., Logan, C., Hu, X., Belfall, B., Worton, R. G., and Ray, P. N. (1987) Nature 328, 434-437[CrossRef][Medline] [Order article via Infotrieve]
3. Klamut, H. K., Gangopadhyay, S. M., Worton, R. G., and Ray, P. N. (1990) Mol. Cell. Biol. 10, 193-205[Medline] [Order article via Infotrieve]
4. Boyce, F. M., Beggs, A. H., Feener, C., and Kunkel, L. M. (1991) Proc. Natl. Acad. Sci. U. S. A. 88, 1276-1280[Abstract]
5. Gorecki, D. C., Monaco, A., Derry, J. M. J., Walker, A. P., Barnard, E. A., and Barnard, P. J. (1992) Hum. Mol. Genet. 1, 505-510[Abstract]
6. D'Souza, V. N., Nguyen, T. M., Morris, G. E., Karges, W., Pillers, D. A., and Ray, P. N. (1995) Hum. Mol. Genet. 4, 837-842[Abstract]
7. Lidov, H. G., Selig, S., and Kunkel, L. M. (1995) Hum. Mol. Genet. 4, 329-335[Abstract]
8. Byers, T. J., Lidov, H. G. W., and Kunkel, L. M. (1993) Nat. Genet. 4, 77-81[Medline] [Order article via Infotrieve]
9. Bar, S., Barnea, E., Levy, Z., Neuman, S., Yaffe, D., and Nudel, U. (1990) Biochem. J. 272, 557-560[Medline] [Order article via Infotrieve]
10. Hugnot, J. P., Gilgengrantz, H., Vincent, N., Chafey, P., Morris, G. E., Monaco, A. P., Berwald-Netter, Y., Koulakoff, A., Kaplan, J. C., Kahn, A., and Chelly, J. (1992) Proc. Natl. Acad. Sci. U. S. A. 89, 7506-7510[Abstract]
11. Rybakova, I. N., Amann, K. J., and Ervasti, J. M. (1996) J. Cell Biol. 135, 661-672[Abstract]
12. Rybakova, I. N. (1997) J. Biol. Chem. 272, 28771-28772[Abstract/Free Full Text]
13. Berko, B., and Swift, M. (1987) N. Engl. J. Med. 316, 1186-1191[Abstract]
14. Muntoni, F., Cau, M., Ganau, A., Congiu, R., Arvedi, G., Matedu, A., and Marrosu, M. G. (1993) N. Engl. J. Med. 329, 921-925[Free Full Text]
15. Milasin, J., Muntoni, F., Severini, G. M., Bartoloni, L., Vatta, M., Krajinovic, M., and Mateddu, A. (1996) Hum. Mol. Genet. 5, 73-79[Abstract/Free Full Text]
16. Nakamura, A., Ikeda, S.-I., Yazaki, M., Yoshida, K., Kobayashi, O., Yanagisawa, N., and Takeda, S.-I. (1997) Am. J. Hum. Genet. 60, 1555-1558[Medline] [Order article via Infotrieve]
17. Kimura, S., Abe, K., Susuki, M., Ogawa, M., Yoshioka, K., Kaname, T., Miike, T., and Yamamura, K. (1997) Dev. Growth Differ. 39, 257-265[CrossRef][Medline] [Order article via Infotrieve]
18. Klamut, H. J., Bosnoyan-Collins, L. O., Worton, R. G., Ray, P. N., and Davis, H. L. (1996) Hum. Mol. Genet. 5, 1599-1606[Abstract/Free Full Text]
19. Hoffman, E. P., Monaco, A. P., Feener, C. C., and Kunkel, L. M. (1987) Science 238, 347-350[Medline] [Order article via Infotrieve]
20. Shizuya, H., Birren, B., Kim, U.-J., Mancino, V., Slepak, T., Tachiri, Y., and Simon, M. (1992) Proc. Natl. Acad. Sci. U. S. A. 8794-8797
21. Christian, C. N., Nelson, P. G., Peacock, J., and Nirenberg, M. (1977) Science 196, 995-998[Medline] [Order article via Infotrieve]
22. Kimes, B. W., and Brandt, B. L. (1976) Exp. Cell. Res. 98, 367-381[Medline] [Order article via Infotrieve]
23. Jainchill, J. L., Aaranson, S. A., and Todaro, G. J. (1969) J. Virol. 4, 549-553[Medline] [Order article via Infotrieve]
24. Gossett, L. A., Kelvin, D. J., Sternberg, E. A., and Olson, E. N. (1989) Mol. Cell. Biol. 9, 5022-5033[Medline] [Order article via Infotrieve]
25. Braun, T., Bober, E., Winter, B., Rosenthal, N., and Arnold, H. H. (1990) EMBO J. 9, 821-831[Abstract]
26. Braun, T., Winter, B., Bober, E., and Arnold, H. H. (1990) Nature 346, 663-665[CrossRef][Medline] [Order article via Infotrieve]
27. Chakraborty, T., Martin, J. F., and Olson, E. N. (1992) J. Biol. Chem. 267, 17498-17501[Abstract/Free Full Text]
28. Murre, C., McCaw, P. S., and Baltimore, D. (1989) Cell 56, 777-783[Medline] [Order article via Infotrieve]
29. Lin, H., and Konieczny, S. F. (1992) J. Biol. Chem. 267, 4773-4780[Abstract/Free Full Text]
30. Buskin, J. N., and Hauschka, S. D. (1989) Mol. Cell. Biol. 9, 2627-2640[Medline] [Order article via Infotrieve]
31. Minty, A., and Kedes, L. (1986) Mol. Cell. Biol. 6, 2125-2136[Medline] [Order article via Infotrieve]
32. Mohun, T. J., Taylor, M. V., Garret, N., and Gurdon, J. B. (1989) EMBO J. 8, 1153-1161[Abstract]
33. Apone, S., and Hauschka, S. D. (1995) J. Biol. Chem. 270, 21420-21427[Abstract/Free Full Text]
34. Kunkel, T. A., Roberts, J. D., and Zakour, R. A. (1987) Methods Enzymol. 154, 367-382[Medline] [Order article via Infotrieve]
35. Fried, M., and Crothers, D. M. (1981) Nucleic Acids Res. 9, 6505-6525[Abstract]
36. Dignam, D. J., Lebovitz, R. M., and Roeder, R. G. (1983) Nucleic Acids Res. 11, 1475-1489[Abstract]
37. Horlick, R. A., and Benfield, P. A. (1989) Mol. Cell. Biol. 9, 2396-2413[Medline] [Order article via Infotrieve]
38. Amacher, S. L., Buskin, J. N., and Hauschka, S. D. (1993) Mol. Cell. Biol. 13, 2753-2764[Abstract]
39. Davis, R., Weintraub, H., and Lassar, A. B. (1987) Cell 51, 987-1000[Medline] [Order article via Infotrieve]
40. Lassar, A. B., Davis, R. L., Wright, W. E., Kadesch, T., Murre, C., Voronova, A., Baltimore, D., and Weintraub, H. (1991) Cell 66, 305-315[Medline] [Order article via Infotrieve]
41. Murre, C., McCaw, P. S., and Baltimore, D. (1989) Cell 56, 777-783[Medline] [Order article via Infotrieve]
42. Jaynes, R. B., Johnson, J. E., Buskin, J. N., Gartside, C. L., and Hauschka, S. D. (1989) Mol. Cell. Biol. 8, 62-70
43. Rosenthal, N., Kornhauser, J. M., Donoghue, M., Rosen, K. M., and Merlie, J. P. (1989) Proc. Natl. Acad. Acad. Sci. U. S. A. 86, 7780-7784[Abstract]
44. Wentworth, B. M., Donoghue, M., Engert, J. C., Berglud, E. B., and Rosenthal, N. (1991) Proc. Natl. Acad. Sci. U. S. A. 88, 1242-1246[Abstract]
45. Shore, P., and Sharrocks, A. D. (1995) Eur. J. Biochem. 229, 1-13[Abstract]
46. Strauss, E. C., and Orkin, S. H. (1999) Methods Enzymol. 304, 572-584[Medline] [Order article via Infotrieve]
47. Molkentin, J. D., Black, B. L., Martin, J. F., and Olson, E. N. (1995) Cell 83, 1125-1136[Medline] [Order article via Infotrieve]
48. Klamut, H. J., Bosnoyan-Collins, L. O., Worton, R. G., and Ray, P. N. (1997) Nucleic Acids Res. 25, 1618-1625[Abstract/Free Full Text]
49. Black, B. L., Molkentin, J. D., and Olson, E. N. (1998) Mol. Cell. Biol. 18, 69-77[Abstract/Free Full Text]
50. Belaguli, N. S., Sepulveda, J. L., Nignam, V., Charron, F., Nemer, M., and Schwartz, R. J. (2000) Mol. Cell. Biol. 20, 7550-7558[Abstract/Free Full Text]
51. Morin, S., Charron, F., Robitaille, L., and Nemer, M. (2000) EMBO J. 19, 2046-2055[Abstract/Free Full Text]
52. Koo, H. S., Wu, H. M., and Crothers, D. M. (1986) Nature 320, 501-506[Medline] [Order article via Infotrieve]
53. Crothers, D. M., Gartenberg, M. R., and Shrader, T. E. (1991) Methods Enzymol. 208, 118-146[Medline] [Order article via Infotrieve]
54. Crothers, D. M., Haras, T. E., and Nadeau, J. G. (1990) J. Biol. Chem. 265, 7093-7096[Free Full Text]
55. Kophenavong, T., Michnowicz, J. E., and Blackwell, T. K. (2000) Mol. Cell. Biol. 20, 261-272[Abstract/Free Full Text]
56. Diagana, T., North, D. L., Jabet, C., Fiszman, M. Y., Takeda, S., and Whalen, R. G. (1997) J. Mol. Biol. 265, 480-493[CrossRef][Medline] [Order article via Infotrieve]
57. Galvagni, F., Cartocci, E., and Oliviero, S. (1998) J. Biol. Chem. 273, 33708-33713[Abstract/Free Full Text]
58. Galvagni, F., Lestingi, M., Cartocci, E., and Oliviero, S. (1997) Mol. Cell. Biol. 17, 1731-1743[Abstract]


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