Identification of a myocardial-specific Prkaa2 enhancer

Because of its central role in the heart as a master regulator of energy balance and homeostasis and due to its regulatory changes during heart failure, AMPK has been extensively studied, but, remarkably, the in vivo transcriptional regulation of the genes encoding AMPK subunits has not previously been investigated. The first intron of the Prkaa2 gene contains a ∼1 kb evolutionarily conserved element marked by activating histone marks in an in vitro model of cardiomyocyte differentiation (Wamstad et al., 2012) (Fig. 1A). We tested this element for enhancer activity in transgenic mouse embryos and found that it functions as a cardiac enhancer from the cardiac crescent stage, throughout embryonic development, and in adulthood in a pattern that appeared essentially identical to the endogenous pattern of Prkaa2 mRNA expression (Fig. 1B-P). Transverse sectioning of X-gal-stained embryos showed that staining was only present in cardiac progenitors at E7.75 and thereafter only in the myocardial layer of the heart at E9.5 and E11.5 (Fig. 1D,G,J,M). The Prkaa2 enhancer did not appear to be active outside of the myocardium, although we cannot rule out activity at later developmental or adult stages in other non-myocardial cell types within the heart.

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Fig. 1.

Identification of a cardiac-restricted Prkaa2 enhancer. (A) Human:mouse conservation (top box), human:opossum conservation (second box), H3K27 acetylation (Wamstad et al., 2012) in cardiomyocytes (third box), and H3K27 acetylation (Wamstad et al., 2012) in cardiac precursors (fourth box) in the Prkaa2 locus. The red-boxed peak highlights the 931 bp Prkaa2 enhancer. Red-filled peaks, noncoding sequences conserved between 75% and 100%; blue-filled peaks, coding sequences conserved between 75% and 100%; white peaks, conservation between 50% and 75%. (B-P) Whole-mount (B,E,H,K,N-P) and sections (D,G,J,M) of X-gal-stained Prkaa2[931]-lacZ transgenic embryos and postnatal hearts. Prkaa2[931] enhancer activity recapitulates the expression pattern of endogenous Prkaa2 detected by whole-mount in situ hybridization (C,F,I,L) from E7.75 through E11.5. e, endocardium; hrt, heart; LV, left ventricle; m, myocardium; NT, neural tube; pcm, precardiac mesoderm; RA, right atrium, RV, right ventricle. Scale bars: 100 µm.

The location of the enhancer in the first intron of Prkaa2 and the concordance of enhancer activity with endogenous Prkaa2 expression (Fig. 1) strongly suggest that this enhancer regulates Prkaa2 expression. As an explicit test of this notion, we used CRISPR/Cas9 to delete the enhancer from the mouse genome and compared Prkaa2 expression in the presence and absence of this enhancer (Fig. S1). Mice of all genotypes (Prkaa2^+/+, Prkaa2^+/enhΔ, Prkaa2^enhΔ/enhΔ) occurred at predicted Mendelian frequency, and no overt phenotypes were observed (data not shown). However, Prkaa2^enhΔ/enhΔ mice had a 64.4% reduction in Prkaa2 expression in the heart at E9.5 compared with Prkaa2^+/+ mice (Fig. S1B). This establishes that this intronic element is a bona fide Prkaa2 transcriptional enhancer. These data also suggest that additional cardiac enhancers for Prkaa2 must exist to account for the remaining 36% of cardiac gene expression in Prkaa2^enhΔ/enhΔ embryos.

The Prkaa2 enhancer is a transcriptional target of MEF2C

We next generated a small series of deletion fragments within the 931 bp Prkaa2 enhancer and found that a 200 bp fragment from nucleotides 429-628 of the 931 bp intronic enhancer was necessary and sufficient to direct expression exclusively to the myocardium at E11.5 (Fig. S2). This 200 bp fragment contains two perfectly conserved MEF2 consensus sites (Fig. S2F), suggesting that this Prkaa2 enhancer might be regulated by MEF2. Indeed, activity of the enhancer was completely abolished when the Prkaa2[931]-lacZ transgene was crossed onto a Mef2c-null background (Fig. 2A,A′). Moreover, endogenous Prkaa2 expression was also significantly reduced by 77% in the hearts of Mef2c-null mice (Fig. S3). Notably, expression of endogenous Prkaa2 was not completely abolished in the absence of MEF2C function, further supporting the likely existence of additional, MEF2C-independent Prkaa2 cardiac enhancers. In electrophoretic mobility shift assays (EMSAs), MEF2C bound specifically to each of the Prkaa2 MEF2 sites (Fig. 2B).

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Fig. 2.

The Prkaa2 cardiac enhancer requires MEF2C for activity. (A,A′) Prkaa2[931]-lacZ transgenic mice were crossed into Mef2c^+/+ (wild type, A) and Mef2c^−/− (A′) backgrounds, and enhancer activity was examined by X-gal staining at E8.5; hrt, heart. (B) Prkaa2 MEF2 site 1 (lanes 1-6) or Prkaa2 MEF2 site 2 (lanes 7-12) was used in EMSA with reticulocyte lysate (−, lanes 1 and 7) or with recombinant MEF2C (+, lanes 2-6 and 8-12). MEF2C efficiently bound to both of the Prkaa2 MEF2 sites (lanes 2 and 8). Binding to each site was competed by an excess of unlabeled control MEF2 site from the myogenin gene (C) or by unlabeled self probe (1) or (2), respectively, but not by mutant versions of the unlabeled competitors [mC, m(1), m(2)]. (C,D) P19CL6 cells were co-transfected with parental pTK-β-gal reporter (lanes 1, 2), wild-type Prkaa2-β-gal (lanes 3, 4), or a mutant version of the Prkaa2-β-gal reporter with both MEF2 sites disrupted (lanes 5, 6). Co-transfection of an expression plasmid for MEF2C (C) or MEF2C-VP16 (D) is indicated with a plus symbol; a minus symbol indicates that an equivalent amount of the parental expression plasmid was added. Results are reported as mean+s.e.m.; n=14 (C) or n=8 (D) independent biological replicates. Note the difference in the values on the x-axes for transactivation by MEF2C (C) versus MEF2C-VP16 (D). *P<0.05, ****P<0.0001, two-way ANOVA with Bonferroni's post-hoc test.

MEF2C significantly activated the Prkaa2 cardiac enhancer in P19CL6, a cardiac progenitor-like cell line, and this activation was dependent on the presence of intact MEF2 sites (Fig. 2C). We also examined the ability of MEF2C-VP16, a fusion of MEF2C with a potent transactivation domain from herpes simplex virus, to activate the Prkaa2 enhancer (Fig. 2D). Similar to wild-type MEF2C, MEF2C-VP16 activated the Prkaa2 reporter in a MEF2 site-dependent fashion (Fig. 2D), but activation was much more robust than by wild-type MEF2C (∼5-fold for MEF2C compared with >2000-fold for MEF2C-VP16).

Cooperative activation of the Prkaa2 enhancer by MEF2C and myocardin

One possible explanation for the dramatic difference in transactivation of the Prkaa2 enhancer by MEF2C-VP16 compared with MEF2C is that P19CL6 cells might be missing one or more MEF2C co-activator proteins required for robust activation, and fusion of the VP16 activation domain compensated for the missing co-factor. The long form of myocardin is restricted to the heart and has been shown to coactivate MEF2 (Creemers et al., 2006). Therefore, to determine if myocardin might be involved in Prkaa2 regulation in vivo, we crossed the Prkaa2[931]-lacZ transgene onto a myocardin-null (Myocd^−/−) background and examined β-galactosidase activity at E9.5 (Fig. 3A). X-gal staining of Myocd^−/− embryos was noticeably weaker than staining of wild-type embryos (Fig. 3A,A′). Using a quantitative luminescence assay, we found ∼80% reduction in β-galactosidase activity in Myocd-null hearts compared with wild type or Myocd heterozygotes (Fig. 3A″). These data indicate that myocardin regulates the Prkaa2 enhancer in vivo.

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Fig. 3.

Myocardin-935 regulates the Prkaa2 cardiac enhancer. (A-A″) Prkaa2[931]-lacZ transgenic mice were crossed into Myocd^+/+ (wild type, A), Myocd^+/− and Myocd^−/− (A′) genetic backgrounds and enhancer activity was examined qualitatively by X-gal staining (A,A′) or quantitatively by chemiluminescence β-galactosidase assay (A″) at E9.5. hrt, heart. Data in A″ are expressed as the mean β-galactosidase activity (+s.e.m.) with the mean activity on the Myocd^+/+ background normalized to a value of 1. n=4 (Myocd^+/+), n=5 (Myocd^+/−) and n=3 (Myocd^−/−) independent biological replicates. *P<0.05, one-way ANOVA with Bonferroni's post-hoc test. (B) P19CL6 cells were co-transfected with the parental pTK-β-gal reporter (lanes 1-4), wild-type Prkaa2-β-gal (lanes 5-8), or mutant versions of the Prkaa2-β-gal reporter containing disruptions in MEF2 site 1 (lanes 9-12), site 2 (lanes 13-16) or both MEF2 sites (lanes 17-20). Co-transfections with expression plasmids for MEF2C and myocardin-935 are indicated with a plus symbol; a minus symbol indicates that an equivalent amount of the parental expression plasmid was added. Results shown are the mean fold activation over the pTK-β-gal reporter in the presence of parental expression vectors+ s.e.m.; n=9 independent biological replicates. ***P<0.001, two-way ANOVA with Bonferroni's post-hoc test.

We next examined cooperative activation of the Prkaa2 enhancer by MEF2C and myocardin-935 in P19CL6 cells (Fig. 3B). MEF2C weakly, but significantly, activated the wild-type Prkaa2-β-gal reporter on its own (Fig. 3B, lanes 5 and 6; Fig. S4). Activation of the wild-type reporter was very potently augmented by cotransfection of a myocardin-935 expression plasmid (Fig. 3B, lanes 6 and 8; Fig. S4). The weak activation of the wild-type reporter by myocardin alone (Fig. 3B, lane 7) is likely to be due to low levels of MEF2 in P19CL6 cells, since mutation of the MEF2 sites in the Prkaa2 enhancer abolished the myocardin-dependent activation of the reporter (Fig. 3B, lane 19). Mutation of either MEF2 site dramatically reduced, but did not abolish, cooperative activation by myocardin and MEF2C (Fig. 3B, lanes 9-16). Mutation of both MEF2 sites completely abolished activation of the reporter by MEF2C and myocardin (Fig. 3B, lanes 17-20). Importantly, no synergy was observed between MEF2C and the short form of myocardin (myocardin-856) on the Prkaa2 enhancer under conditions in which myocardin-935 potently augmented MEF2C-dependent transactivation of the enhancer (Fig. S4).

Bridging of two MEF2 sites by myocardin dimerization

MEF2C and myocardin activated the Prkaa2 reporters with a single intact MEF2 site by ∼10-fold but activated the wild-type reporter with two intact MEF2 sites by more than 60-fold (Fig. 3B), suggesting that the two sites function cooperatively. Previous work has shown that myocardin homodimerizes through a conserved leucine zipper (LZ) domain and that homodimerization facilitates stronger activation of SRF-dependent reporter genes containing two or more SRF binding sites (Wang et al., 2003). Based on these observations, we hypothesized that myocardin dimerization might facilitate interaction between the two Prkaa2 MEF2 sites, and we tested this notion using an in vitro pull-down experiment (Fig. 4A,B). Addition of MEF2C or myocardin-935 alone resulted in minimal pull-down of MEF2 site 1 by MEF2 site 2 (Fig. 4B, lane 1). By contrast, inclusion of both MEF2C and myocardin-935 resulted in robust and highly significant pull-down of MEF2 site 1 by MEF2 site 2 (Fig. 4B, lane 4). Mutation of the myocardin LZ motif in a manner predicted to disrupt homodimerization (Wang et al., 2003) completely abolished the complex and resulted in only baseline pull-down of MEF2 site 1 (Fig. 4B, lane 5). These experiments demonstrate that myocardin-935 dimerization can facilitate interaction between two MEF2C-bound MEF2 sites.

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Fig. 4.

Bridging of MEF2C-bound MEF2 sites by myocardin-935. (A) Schematic of the in vitro pull-down assay. (B) qPCR detection of co-precipitated MEF2 site 1 after incubation with biotinylated MEF2 site 2 in the presence of reticulocyte lysate control (lane 1), MEF2C alone (lane 2), myocardin-935 (wt) alone (lane 3), MEF2C plus myocardin-935 (lane 4), or MEF2C plus a leucine zipper mutant form of myocardin-935 (LZ mut) (lane 5). Results are presented as mean fold enrichment over the reticulocyte lysate control+s.d. ****P<0.0001, two-way ANOVA with Bonferroni's post-hoc test. (C-H) The MEF2 sites in the Prkaa2 cardiac enhancer act synergistically in vivo. The wild-type Prkaa2[931]-lacZ transgenic reporter (C) and versions containing mutations in MEF2 site 1 (D), site 2 (E) or both MEF2 sites (F) were used to generate multiple independent transgenic lines or F0 embryos, and representative E11.5 embryos are shown. hrt, heart; LV, left ventricle. (G,H) The presence of both MEF2 sites is required for Prkaa2 enhancer activity in the adult heart. (I) Quantitation of β-galactosidase activity in E11.5 hearts from each of the Prkaa2[931]-lacZ transgenic reporter constructs shown in C-F. Each point on the graph represents a single embryonic heart from an independently generated transgenic embryo. Data are expressed as mean RLU/µg of excised heart tissue+s.e.m. Note the log scale on the y-axis. *P<0.05, **P<0.01, two-way ANOVA with Bonferroni's post-hoc test.

The two MEF2 sites in the Prkaa2 cardiac enhancer exhibit cooperative activity in vivo

To determine whether the Prkaa2 MEF2 sites are required for enhancer activity in vivo, we generated transgenic mouse embryos with the MEF2 sites mutated singly and in combination (Fig. 4C-H). The wild-type (wt) Prkaa2 enhancer directed robust expression in E11.5 and adult hearts (Fig. 4C,G). Mutation of both MEF2 sites resulted in complete loss of detectable X-gal staining in every transgenic founder examined at E11.5 (Fig. 4F) and in adult hearts (Fig. 4H). By contrast, mutation of either of the MEF2 sites alone reduced (but did not completely abolish) enhancer activity (Fig. 4D,E). These observations are consistent with the transactivation data (Fig. 3B), where we observed that mutation of a single site profoundly reduced, but did not completely abolish, transactivation whereas mutation of both MEF2 sites completely abolished transactivation by MEF2C and myocardin-935.

To determine if the Prkaa2 MEF2 sites function cooperatively in vivo, we generated numerous independent F0 transgenic founder embryos with each of the transgene constructs, and quantified β-galactosidase activity in E11.5 hearts (Fig. 4I). The wild-type enhancer showed consistently strong activity (n=10 independent transgenic lines) with only a few outliers and a mean activity of 792,489 RLU/µg of cardiac tissue. Mutation (m) of either MEF2 site resulted in a profound and significant diminution of activity (mMEF2 site 1, n=12 independent transgenic lines, =194,591; mMEF2 site 2, n=18 independent transgenic lines, =96,627). Mutation of both MEF2 sites [mMEF2(1+2)] completely abolished enhancer activity in every transgenic founder examined (n=6 independent transgenic lines, =1700). These data demonstrate a cooperative (greater than additive) relationship between the two Prkaa2 MEF2 sites in vivo. Interestingly, nearly all Prkaa2-lacZ transgenic lines with two intact MEF2 sites exhibited strong activity that ranged by less than a single order of magnitude, whereas transgenic embryos made from Prkaa2-lacZ constructs with only a single intact MEF2 site showed far greater variability ranging over nearly three orders of magnitude (Fig. 4I); this suggests that the presence of two functional MEF2 sites buffers the enhancer from silencing due to positional effects (Elgin and Reuter, 2013).

Paired MEF2 sites are prevalent in predicted cardiac enhancers

We analyzed predicted enhancers from mouse embryonic stem cells (ESCs), ESC-derived cardiac cells (cardiomyocytes and cardiac progenitors) and liver cells (Creyghton et al., 2010; Wamstad et al., 2012) and found that paired MEF2 sites occur in ∼30% of predicted cardiac enhancers. Interestingly, paired MEF2 sites occur 1.7 times more frequently in predicted cardiac enhancers than in liver enhancers (95% CI 1.5-1.9) and 2.0 times more frequently than in ESCs (95% CI 1.7-2.3) (Tables S1 and S2). The significant enrichment of paired MEF2 sites in predicted cardiac enhancers compared with liver and ESC enhancers suggests that natural selection has favored this arrangement in cardiac enhancers, possibly due to an advantage in gene expression conferred by myocardin bridging of the sites. Future studies will determine how the sequence and spacing of paired MEF2 sites in the Prkaa2 enhancer and other cis-regulatory elements determines the timing and robustness of cardiac gene activation.