Vangl2-Regulated Polarisation of Second Heart Field-Derived Cells Is Required for Outflow Tract Lengthening during Cardiac Development
Congenital heart defects are common, affecting almost 1% of all live births. Many of these affect the outflow region, where the aorta and pulmonary trunk connect with the main ventricular chambers. Congenital heart defects arise from disruption of normal developmental processes and can be modelled in mice. Thus, studying normal development, together with mouse mutants that develop heart malformations, should shed light on why these common anomalies arise. We have studied cardiac development in a mouse mutant for the Vangl2 gene, a key component of the planar cell polarity (PCP) pathway. This pathway controls the orientations of cells in epithelia and during directional cell migration. Here, we show that PCP signalling is required by cells derived from the second heart field, which forms the outflow tract walls. We show that in the absence of Vangl2, the cells within the distal outflow tract walls are non-polarised and disorganised. As a consequence the outflow tract is shortened and does not align properly with the ventricles. Thus, we show why disruption of a key PCP gene leads to outflow tract malformations. This is important for understanding heart development, but also more generally for understanding how PCP signalling regulates growth of tubular structures.
Published in the journal:
Vangl2-Regulated Polarisation of Second Heart Field-Derived Cells Is Required for Outflow Tract Lengthening during Cardiac Development. PLoS Genet 10(12): e32767. doi:10.1371/journal.pgen.1004871
Category:
Research Article
doi:
https://doi.org/10.1371/journal.pgen.1004871
Summary
Congenital heart defects are common, affecting almost 1% of all live births. Many of these affect the outflow region, where the aorta and pulmonary trunk connect with the main ventricular chambers. Congenital heart defects arise from disruption of normal developmental processes and can be modelled in mice. Thus, studying normal development, together with mouse mutants that develop heart malformations, should shed light on why these common anomalies arise. We have studied cardiac development in a mouse mutant for the Vangl2 gene, a key component of the planar cell polarity (PCP) pathway. This pathway controls the orientations of cells in epithelia and during directional cell migration. Here, we show that PCP signalling is required by cells derived from the second heart field, which forms the outflow tract walls. We show that in the absence of Vangl2, the cells within the distal outflow tract walls are non-polarised and disorganised. As a consequence the outflow tract is shortened and does not align properly with the ventricles. Thus, we show why disruption of a key PCP gene leads to outflow tract malformations. This is important for understanding heart development, but also more generally for understanding how PCP signalling regulates growth of tubular structures.
Introduction
Malformations affecting the outflow of the heart are a major cause of morbidity and mortality in childhood. While many of these malformations occur sporadically, studies of families with congenital heart defects, alongside animal studies, have revealed that phenotypically discrete heart malformations can have diverse causes. These can involve disruption of a number of different genes, embryonic lineages or developmental processes. Furthermore, dissimilar malformations, including double outlet right ventricle, common arterial trunk, and tetralogy of Fallot, may appear in offspring sharing the same genetic defect and can therefore be considered within a spectrum of malformation with similar underlying causes [1]. Clarifying the fundamental processes that underpin cardiovascular development is essential to understand this complexity.
The primitive heart tube is derived from the cardiac crescent, or first heart field, at embryonic day (E) 8.5 of mouse development. Subsequently, the second heart field (SHF), which lies dorso-anteriorly to the primary cardiac crescent, adds cells to both the venous (inflow) and arterial (outflow) poles to lengthen the primitive heart tube [2], [3], [4]. The outflow tract develops as a bi-layered tube composed of an outer layer of myocardium, with an inner endocardial lining, both derived from the SHF [5]. This is connected proximally to the common ventricle and to the developing pharyngeal arch arteries at its distal end. Studies in chicken have shown that there is a focus of proliferative cells in the dorsal pericardial wall that act as a source of cells for both poles of the heart [6]. Moreover, these studies support the idea that the cells move into the outflow as an epithelial sheet, rather than as individually migrating cells. Although the precise morphogenetic mechanisms underpinning outflow development are still being elucidated, the targeted disruption of a number of genes within the SHF, including Isl1, Fgf8, Tbx1, and Tbx20, give rise to outflow tract malformations in mice (reviewed in [7]). Furthermore, mutations in TBX1 [8] and common variants in ISL1 [9] have been found in human patients with outflow tract malformations, indicating a developmentally conserved role for the SHF during cardiac development. Detailed studies have shown that the transcriptional network involving Tbx1 and Isl1 is required to maintain SHF cells in a proliferative, progenitor-like state before they are added to the outflow tract [10]; in their absence the outflow tract is shortened. Following outflow tract septation, this results in mal-alignment of the aorta and pulmonary trunk with the ventricular chambers [5], [11]. Despite insight into the transcriptional network that regulates the maintenance of SHF progenitors before they reach the poles of the heart, there is limited information about the characteristics and behaviour of the cells as they add to the outflow tract.
Endocardial cushions form along the length of the developing outflow tract and by way of complex processes of cell migration, growth and remodelling, result in the separation of the initially single vessel into the aortic and pulmonary trunks (reviewed in [12]). Neural crest cells (NCC), originating in the cranial neural tube, migrate long distances into the pharyngeal arches and endocardial cushions and are involved in septation and alignment of the outflow vessels [13], [14], [15]. The processes regulating NCC migration have been studied in some detail, and at least in frogs and zebrafish, contact inhibition of locomotion, regulated at least in part by the planar cell polarity signalling pathway (see below) is implicated [16], [17]. Thus, a variety of cell types and complex morphological processes contribute to the developing outflow tract.
The planar cell polarity (PCP) pathway is a non-canonical Wnt pathway, which acts to regulate cell polarity within the plane of an epithelium. Studies in Drosophila wing, eye and abdomen have shown that polarity between adjacent cells is co-ordinated by the asymmetrical localisation of core PCP factors. Vangl2 (Strabismus), Flamingo and Prickle accumulate proximally in polarised cells, while Dishevelled, Frizzled, Flamingo, and Diversin (Diego) accumulate distally [18]. PCP signalling has also been implicated in the regulation of apico-basal polarity, and directional cell migration [19], [20], [21]. Outflow tract malformations, including septation defects, are common in mice following the disruption of PCP genes (reviewed in [22]), although the lineage requirement for PCP signalling in heart development remains unclear. Loop-tail (Lp) mice carry a mutation in the Vangl2 gene, encoding a key component of the PCP pathway. Lp/Lp mice display a number of malformations associated with disrupted PCP signalling, including misorientation of stereocilia in the cochlea and utricle [23], [24] and craniorachischisis [25]. We have previously shown that Lp/Lp embryos have a spectrum of cardiac defects that affect the outflow region of the heart [26], including double outlet right ventricle, common arterial trunk, abnormal patterning of the pharyngeal arches and ventricular septal defects. The mutant embryos also have abnormalities in the ventricular wall that include the coronary arteries [27]. Thus, the spectrum of defects seen in Lp/Lp mice could result from disruption of several cell types. Here we investigate the role of Vangl2 during outflow tract development using a novel tissue-specific knockout of the Vangl2 gene. We highlight a role for Vangl2 specifically within the SHF and show that Vangl2 is essential for forming the epithelial distal component of the elongating outflow vessel.
Results
Spectrum of outflow abnormalities in Lp mice
We have shown previously that Lp/Lp embryos present a number of cardiac anomalies [26]. To begin to characterise early heart formation in these mutants and as a prelude to lineage-based analyses, cardiac-specific markers were analysed by in situ hybridization, in order to determine whether the chambers formed properly. The expression patterns of the chamber markers Mlc2a, Mlc2v and Nppa, and outflow markers including Tbx20, were examined in embryos from Lp litters at E10.5. Whilst none of these markers showed reproducible expression differences between control and Lp/Lp embryos (n = 2–3 for each gene examined), aberrant heart looping could clearly be seen in the latter; the outflow tract was shorter and the right ventricle was hypoplastic, although to a varying extent, in all Lp/Lp when compared with controls (>50 embryos examined in total; Fig. 1 A,B, S1 Fig.). Transverse sections of Lp/Lp hearts at E14.5 revealed double outlet right ventricle (Fig. 1 C,D) as previously described [26]. To begin to establish the cell type that requires Vangl2 signalling for outflow tract development, we first crossed the Lp mice with the Wnt1-Cre line. However, no defects in NCC migration were observed in Lp/Lp embryos from E10.5, with the distribution of Wnt1-Cre-positive cells indistinguishable from that of control littermates (Fig. 1 E–H ).
Disorganised movement of Isl1-positive cells into the outflow tract in Lp/Lp
Isl1 is expressed by all SHF progenitor cells and thus can be used for lineage tracing of the SHF [5]. We therefore asked whether Isl1-Cre-expressing SHF derivatives contribute normally to the heart in Lp/Lp embryos. Comparison with stage-matched controls revealed no abnormalities in the overall distribution of SHF-derivatives in the pharyngeal and cardiac regions of the Lp/Lp embryos (Fig. 1 I–L). As development progresses, the continued expression of Isl1 protein is confined to non-differentiated SHF progenitors; it is down-regulated as they differentiate [5]. At E9.5, Isl1-expressing cells localised to the mesenchyme of the dorsal wall of the aortic sac and the distal outflow tract (Fig. 1M). Whilst Isl1 staining was broadly similar between wild type and Lp/Lp littermates, Isl1-expressing cells appeared disorganised in the distal outflow tract in the mutant embryos (Fig. 1 compare N′ with M′). This subtle anomaly was highly reproducible (n = 10). Together, these data suggested that there could be an abnormality in SHF-derived cells in the distal outflow tract.
Global loss of Vangl2 using Vangl2flox mice recapitulates the Lp/Lp phenotype
The gross morphological defects, including craniorachischisis and axial rotation defects, together with the loss of Vangl2 in all body cells, limit the use of Lp for studying the causes of the cardiac malformations. To clarify the role that Vangl2 plays during heart morphogenesis, we produced a floxed allele of Vangl2, in which exon 4, encoding the trans-membrane domains, is flanked by loxP sites (Fig. 2A). A neomycin selection cassette, flanked by FRT sites, was placed downstream of exon 4. Vangl2neo/neo mice, which retain the neomycin selection cassette within the construct, were hypomorphic for Vangl2, with 2/3 displaying craniorachischisis and 1/3 spina bifida only (S2 A–H Fig.). The neoR cassette was subsequently removed by crossing the Vangl2neo mice with FLPe mice, to give Vangl2flox mice. Recombination of the resulting construct following the expression of Cre is predicted to produce a premature stop codon that gives rise to a small 8 KDa protein, which lacks the four trans-membrane domains and C-terminal PDZ-binding domain required for interaction of Vangl2 with other proteins [28], [29].
Vangl2flox mice were crossed with Sox2-Cre and PGK-Cre mice to produce embryos containing the truncated Vangl2 construct in all cells (Fig. 2 B–K). Inter-crossing Vanglflox/+; Sox2-Cre or Vangl2flox/+; PGK-Cre mice with Lp/+ mice generated Vangl2flox/Lp; Sox2-Cre and Vangl2flox/Lp; PGK-Cre embryos that were indistinguishable from stage-matched Lp/Lp embryos, showing craniorachischisis and heart malformations (n = 4; S2 I–P Fig.). Thus, Lp and the Vangl2 deletion allele failed to complement.
We next asked whether global knockout of Vangl2 with Sox2-Cre recapitulated the Lp/Lp phenotype (Fig. 3 A–H). Indeed, Vangl2flox/flox; Sox2-Cre embryos had a shortened body axis and craniorachischisis (Fig. 3 compare G with C). Sectioning at E14.5 confirmed that the Vangl2flox/flox; Sox2-Cre embryos had heart malformations, including double outlet right ventricle, ventricular septal defects and pharyngeal arch remodelling defects, as are seen in Lp/Lp embryos (Fig. 3H and S3 A,B Fig. compare with Fig. 3D and [26]). Similar results were obtained using the PGK-Cre line in place of Sox2-Cre (S3 E–H Fig.). Thus, our novel Vangl2flox allele, when knocked out globally, recapitulated the phenotypes observed in Lp/Lp mutants and consequently was a potentially useful tool for genetically dissecting the Lp/Lp phenotype.
Specific deletion of Vangl2 within the SHF recapitulates the Lp/Lp outflow phenotype
In order to determine the tissue-specific requirement for Vangl2 during heart development, we used a number of lineage-specific Cre driver lines to delete Vangl2 in a targeted manner. Although our studies in Lp/Lp had suggested that NCC deficiency was unlikely to be the cause of the outflow defects, we could not rule out more subtle defects in their function. Therefore, to exclude the possibility that Vangl2 is required in NCC for outflow tract development, we inter-crossed Vangl2flox mice with the Wnt1-Cre line. Vangl2flox/flox; Wnt1-Cre embryos were indistinguishable from control littermates with both a normal external appearance and normal hearts at E14.5 (n = 6; Fig. 4 A,B,E,F). Moreover, Vangl2flox/flox; Wnt1-Cre animals (n = 3) were viable and indistinguishable from their control littermates at 28 days after birth. Indeed, close analysis of the expression pattern of Wnt1-Cre compared with that of Vangl2 suggested that Vangl2 is not expressed by NCC, and that there was no change in the expression pattern of Vangl2 in the Vangl2flox/flox; Wnt1-Cre embryos at least at the stages when NCC are migrating into the heart (S4 Fig.). Thus, Vangl2 does not appear to be required by NCC for normal development of the outflow tract of the heart.
In order to test directly our hypothesis that Vangl2 is required in the SHF, we inter-crossed the Vangl2flox mice with Isl1-Cre and confirmed loss of Vangl2 in the outflow tract by immunofluorescence at E9.5 (S5 A–I Fig.). In contrast, Vangl2 expression was maintained outside the Isl1-Cre expression domain (S5I Fig.). While externally, the E14.5 Vangl2flox/flox; Isl1-Cre embryos were indistinguishable from their control littermates (Fig. 4 C,G), histological sectioning revealed double outlet right ventricle in 14/15 of the mutant embryos. Moreover, they all had a sub-aortic ventricular septal defect (Fig. 4 D,H and S5 N–S Fig.). An abnormality in the myocardialisation of the outflow cushions was also observed in Vangl2flox/flox; Isl1-Cre embryos (S6 Fig.), as was seen in Lp/Lp [30]. However, there were no abnormalities in pharyngeal arch patterning or the ventricular wall (S5 Fig.). Subsequent analysis at earlier stages (E9.5–E10.5) showed that the embryos had a markedly shortened outflow tract (S5 J–M Fig.). These data exclude the possibility that the outflow tract anomalies are secondary to the gross abnormalities in body patterning seen in Lp/Lp. They do, however, support the idea that Vangl2 plays a specific role in the SHF.
We asked whether the role of Vangl2 is restricted to the SHF or might play a more general role in cardiac progenitor populations. To test this idea, we crossed the Vangl2flox mice with Nkx2.5-Cre mice; Nkx2.5-Cre is expressed throughout the primitive heart tube but also in the cells derived from the SHF [31], [32]. Surprisingly, analysis of Vangl2flox/flox; Nkx2.5-Cre embryos at E15.5 revealed no obvious structural cardiovascular abnormalities (n = 4; Fig. 4 I,J,M,N). Our analysis of the Nkx2.5-Cre expression pattern largely confirmed previous reports, although we observed patchy expression in the outflow tract, compared with much broader and higher level expression in the left ventricle and atria (S7 Fig.). Moreover, Vangl2 was maintained in the distal outflow of Vangl2flox/flox; Nkx2.5-Cre embryos at E9.0 (S7 Fig.). This suggests that Nkx2.5-Cre, at least in our hands, may not be driving high enough levels of Cre to fully delete Vangl2 in the outflow tract.
Finally, as we had previously shown abnormalities in the outflow tract myocardium in Lp mutants [30], and because Isl1-Cre also drives expression in endocardial cells in the outflow tract (Fig. 5B), we wanted to establish whether Vangl2 is required in differentiated cardiomyocytes or the endocardium. To investigate this, we inter-crossed the Vangl2flox mice with Mlc2v-Cre mice, to drive Cre in the outflow and ventricular myocardium. At E9.5–E10.5, Mlc2v-Cre was not expressed in the outflow tract myocardium although it was found in this tissue by E12.5 (S6 C,D Fig.). Deletion of Vangl2 in the Mlc2v-Cre expression domain resulted in embryos with a normal outflow (n = 6; Fig. 4 K,L,O,P). Thus, although Vangl2 expression is maintained in the outflow myocardium at E12.5 (S6 E,F Fig.), this is not required for outflow tract lengthening and alignment of the the great arteries with the ventricles. Intercrossing of Vangl2flox mice with Tie2-Cre mice, to selectively knock out Vangl2 in the endocardium, also resulted in mice with normal outflow tract development (S8 Fig.). Thus, these data support the idea that Vangl2 is required in undifferentiated SHF cells, rather than playing later roles in outflow tract remodelling.
Vangl2 demarks a transition zone in the distal outflow tract
Having established that Vangl2 is required in undifferentiated outflow tract precursors (expressing Isl1), derived from the SHF, we next investigated its role in this population. Normally, undifferentiated SHF cells move from the mesothelial dorsal pericardial wall into the distal outflow tract where they begin to differentiate into cardiomyocytes. Thus, we defined a transition zone in the distal outflow tract where SHF-derived cells lose their progenitor phenotype and differentiate (Fig. 5A). We hypothesised that Vangl2 may be playing a key role in this region, regulating this transition from the progenitor to differentiated phenotype. We focussed our studies at E9.0–E9.5, as this is the period just before (E9.0; approximately 17 somite pairs) and as the first abnormalities in the outflow tract wall become apparent (at E9.5; approximately 23 somite pairs).
Vangl2 protein, shown by immunofluorescence, was present in all the cells of the dorsal pericardial and distal outflow tract walls, into the differentiated myocardium, and also in the endocardium (Fig. 5 B–F). However, the spatial distribution of Vangl2 was not uniform throughout this region at E9.0–E9.5. Within the dorsal pericardial and the most distal outflow tract walls, Vangl2 was enriched in the basal cell membrane, as shown by its colocalisation with β-catenin (Fig. 5 B,C,E). Further proximally however, Vangl2 was seen diffusely throughout the cytoplasm (Fig. 5 B,D,F). As mutations that lead to loss of membrane localisation disrupt Vangl2 function and result in the Lp/Lp phenotype [33], this suggests that Vangl2 is likely to be playing its major roles in the dorsal pericardial wall or distal outflow tract.
To determine at which stage SHF cells change their expression profile from that of a progenitor to a differentiated cardiomyocyte, relative to the distribution of Vangl2, we analysed the expression of cardiac troponin I, which is expressed in differentiated cardiomyocytes (Fig. 5 G–J). At E9.0, cardiac troponin I immuno-reactivity was found at low levels in the most distal outflow tract wall, but became increasingly abundant proximally as the cells differentiated into cardiomyocytes (Fig. 5I). At the same stage, all cells in the dorsal pericardial wall and in the transition zone expressed Isl1 protein, localised within the nucleus. However, nuclear-localised Isl1 was abruptly lost in more proximal cells, where Vangl2 became cytoplasmic (Fig. 5 K–N). Thus, whereas all three markers overlapped in the most distal outflow tract, loss of membrane-associated Vangl2 corresponded to the loss of nuclear Isl1, defining the proximal boundary of the transition zone where the cells had become differentiated cardiomyocytes.
Loss of Vangl2 disrupts cellular organisation and polarity in the distal outflow tract
We next wanted to clarify how Vangl2, as a PCP protein that would normally act within the plane of an epithelium, is functioning in the distal outflow tract. We first investigated the distribution of the adherens junction protein β-catenin, which marks the baso-lateral compartment of epithelial cells, together with the extracellular matrix protein laminin, which is found associated with the basal lamina of epithelial cell layers. At E9.0, the distal outflow wall appeared less organised in Vangl2flox/flox; Isl1-Cre embryos than their control littermates, with reduced staining of β-catenin and laminin (Fig. 6 A–H). This was before outflow shortening was apparent in the mutant embryos. By E9.5, whereas the transition zone had the phenotype of an organised pseudo-stratified epithelium in the controls, the region was markedly disorganised and was becoming thickened in the mutant embryos (Fig. 6 P,R, compare with L,Q, and S5 K,M Fig). β-catenin was lost from the lateral walls of cells of the transition zone in the mutants (Fig. 6N, compare with J), and laminin was absent in some areas of the mutant transition zone and was no longer basally restricted in others (n = 3; Fig. 6P, compare with L). A similar abnormality in the distribution of fibronectin was also observed in the Vangl2flox/flox; Isl1-Cre embryos (S9 Fig.). Interestingly, laminin was always basally distributed more proximally in the Vangl2flox/flox; Isl1-Cre outflow tract, where the wall is composed of differentiated cardiomyocytes (S9 Fig.). These findings were highly reproducible. Thus, whereas the cells of the transition zone in the control distal outflow tract had the appearance of a pseudo-stratified epithelium and had polarised expression of epithelial markers, the epithelium was disorganised and thickened in the Vangl2flox/flox; Isl1-Cre embryos. Moreover, polarised expression of markers was disrupted. In contrast, comparable analyses of Vangl2flox/flox; Nkx2.5-Cre outflow tract showed only a mild phenotype in the mutant embryos (S9 Fig.), supporting the lack of structural outflow tract abnormalities in this cross.
As asymmetrical cell division is regulated by Vangl2 in some tissues [34] we asked whether disruption of this process might account for the disorganised and thickened epithelium of the transition zone in the mutant embryos. However, we found little or no cell division in the distal outflow tract at E9.0–E9.5, as suggested previously [6], indicating that this is unlikely to be the mechanism underlying the disorganisation observed (S10 Fig.). In order to investigate the possibility of disrupted polarity in more detail, we immuno-stained the microtubule organising centre (MTOC; recognised by γ-tubulin) which is polarised in epithelial cells and localised to the apical side of the cell in the transition zone of control embryos (Fig. 6 Q,S). In contrast, this was much more variable in the transition zone cells of Vangl2flox/flox; Isl1-Cre embryos (Fig. 6 R,T), with MTOCs commonly found on the basal side of the cell layer. Statistical analysis (Chi Square) showed this difference was highly significant (p<0.001). This suggests that PCP and/or apical-basal polarity is disrupted in the distal outflow wall in the absence of Vangl2.
We studied the phenotype of the SHF-derived cells more closely as they moved from the mesothelial dorsal pericardial wall into the outflow tract, by looking at other markers associated with polarised epithelia that are expressed in an apical-basal polsarised manner. E-cadherin, an adherens junction-associated protein of epithelial cells was expressed only at low levels in the dorsal pericardial wall, while a related junctional protein, N-cadherin, was not detected in this tissue (Fig. 7 A–D), supporting the idea that this is not a typical epithelium. Within the pseudo-stratified epithelium of the distal outflow tract however, both of these proteins were expressed in a polarised manner, being enriched at the apical-basal boundary (Fig. 7 E,G,L,M). This suggests that as cells move into the distal outflow tract they take on a more overt epithelial phenotype. As in control embryos, E-cadherin expression was up-regulated in the distal outflow of Vangl2flox/flox; Isl1-Cre mutants at E9.0–E9.5, in comparison to the dorsal pericardial wall. However, it was mislocalised with staining found throughout the baso-lateral compartment of the cells (Fig. 7 E,G,H,J and S11 Fig.). The subcellular localisation of N-cadherin expression was also perturbed in the distal outflow tract of Vangl2flox/flox; Isl1-Cre embryos, with loss of enrichment at the apical-basal boundary (Fig. 7 L,M,O,P).
We analysed other proteins known to be compartmentally restricted in epithelial cells. Analysis of PKCζ in the distal outflow tract revealed that whilst the protein was markedly enriched in the apical compartment of cells in the transition zone of control embryos, this apical enrichment was lost in Vangl2flox/flox; Isl1-Cre embryos (Fig. 7 F,G,I,J and S11 Fig.). Scrib has been implicated in regulating epithelial cell adhesion and has been shown to physically interact with Vangl2 in epithelial cells [35], although it does not do so in the early myocardium [36]. Scrib was localised to the baso-lateral compartment of cells within the distal outflow tract wall in control embryos, but was enriched at the apical-basal boundary. In Vangl2flox/flox; Isl1-Cre embryos, Scrib was no-longer enriched at the apical-basal boundary (arrows in Fig. 7 K,M,N,P). This abnormality was restricted to the distal outflow tract, with normal Scrib expression seen in the dorsal pericardial wall and pharyngeal endoderm although both of these tissues also express Isl1-Cre (S11 Fig.), and in epidermis, which does not express Isl1-Cre. Thus, deletion of Vangl2 from SHF cells results in the disruption of both PCP and apical-basal polarisation and loss of epithelial phenotype in the distal outflow tract wall.
Vangl2 retains SHF cells as undifferentiated progenitors
We lastly wanted to establish how the disruption of polarity and loss of epithelial phenotype impacted on the fate of the cells as they move through the distal outflow walls. We investigated whether the expression of either cardiomyocyte differentiation markers or Isl1 was altered in the distal outflow wall of Vangl2flox/flox; Isl1-Cre mutants at E9.0–E10.5. At E9.0 we observed that cardiac troponin I was expressed initially at very low levels within the distal outflow wall of control embryos, becoming progressively more strongly expressed proximally (as shown in Fig. 5). In contrast, high-level expression appeared more distally in Vangl2flox/flox; Isl1-Cre littermates (Fig. 8 A,D). Desmin, which is expressed at elevated levels by cardiomyocytes, but is also found at lower levels in smooth muscle cells at this stage, was also expressed at higher levels more distally in the mutant embryos (Fig. 8 B,E). As expected, we observed a similar disorganisation of Isl1-expressing cells in the distal outflow of Vangl2flox/flox; Isl1-Cre as was observed in Lp/Lp embryos (Fig. 8 C,F). However, it was striking that nuclear Isl1 localisation was lost more distally in the distal outflow wall of Vangl2flox/flox; Isl1-Cre than in control embryos. Notably there was a significant amount of non-nuclear Isl1 observed in cells in control and mutant outflow walls (Fig. 8 C,F). To confirm the findings of premature differentiation in the distal outflow tract of Vangl2flox/flox; Isl1-Cre, we examined the expression of other differentiation markers at E10.5. Similar results to those observed for cardiac troponin I were found using an antibody to myosin heavy chain (MF20; Fig. 8 H,J). Moreover, when we examined the expression of αSMA, which at these stages labels both smooth muscle cells and differentiating cardiomyocytes, it was also expressed at high levels more distally in the mutant embryos than in control littermates (Fig. 8 G,I). Thus, Vangl2flox/flox; Isl1-Cre cells lose their progenitor phenotype and differentiate earlier than those of control embryos. Together, our data suggest that Vangl2 is required to establish the epithelial phenotype of cells in the distal outflow tract wall and that this epithelialisation is required to maintain SHF-derived cells in an organised, polarised state which maximises outflow tract lengthening. This allows normal alignment of the great arteries with the ventricular chambers
Discussion
The spontaneously occurring Lp mutant has been used to study the role of Vangl2 in cardiac development [26], [27], [30]. However, the gross morphological defects that are characteristic of Lp/Lp, including craniorachischisis and incomplete axial rotation, limit its use in dissecting out the role of Vangl2 during heart morphogenesis. We originally suggested that the cardiac looping defects observed in the Lp/Lp may be secondary to the severe neural tube closure and axial turning defects [26]. Indeed, the aortic arch abnormalities that are highly penetrant in Lp/Lp and in the Vangl2flox/flox; Sox2-Cre and Vangl2flox/flox; PGK-Cre mutants described here, may be secondary to these gross abnormalities in body form, as they are only observed in the presence of craniorachischisis. In contrast, we show that the outflow tract anomalies are primary defects. The complexity added by the presence of other embryonic defects, together with the contributions of a number of different cell populations to the developing outflow tract, makes analysis of a global loss of Vangl2 inadequate for the purpose of establishing its precise role in heart development. Here we have described the generation of a conditionally targeted deletion of Vangl2, which when expressed globally recapitulates the outflow anomalies observed in Lp/Lp. Using this model, we have shown that the expression of Vangl2 in the Isl1-Cre expressing SHF is essential for the normal development of the outflow tract.
Our data suggests that it is the expression of Vangl2 in the undifferentiated SHF (Isl1-Cre expressing) population of the distal outflow tract that is critical for outflow tract development, as its deletion in the Mlc2v-Cre-expressing outflow myocardium and Tie2-Cre-expressing endothelium led to normal outflow tract development. However, as well as finding outflow tract shortening as early as E9.5, abnormalities in movement of muscle cells from the outflow tract wall into the cushions (the process of myocardialisation) was also found in the Vangl2flox/flox; Isl1-Cre embryos at E13.5, as in Lp/Lp embryos [30], showing that the outflow myocardium does not recover from its early abnormalities. In the distal outflow tract wall, cells transition from an undifferentiated form (expressing nuclear Isl1 protein) to differentiated myocardium (with a consequent loss of nuclear Isl1 and upregulation of striated muscle markers including myosin heavy chain and cardiac troponin I). Intriguingly, Vangl2 is lost from the cell membrane and is localised to the cytosol at the proximal boundary of the transition zone, where the cells differentiate to myocardium. Thus, this switch from membrane to cytoplasmic Vangl2, together with the loss of nuclear Isl1, defines the proximal boundary of the transition zone. There is good evidence to suggest that Vangl2 is active when it is membrane-associated, as mutations that block membrane-association block function [33]. Thus, we suggest that it is the membrane-localisation of Vangl2 in the transition zone that imparts planar polarity on the cells, maintaining their epithelial phenotype. When this membrane-association is lost, the cells lose their typical epithelial appearance and differentiate. Although Vangl1, a close homologue of Vangl2 is expressed in the early embryo, its expression domain is more restricted than that of Vangl2 [37],[38]. Vangl1 mutants do not have an outflow tract phenotype [37]. Thus, it seems likely that Vangl2 is the principal Vangl gene acting in the early heart. We did not see an outflow tract phenotype when we inter-crossed the Vangl2flox mice with Nkx2.5-Cre line. However, analysis of the Nkx2.5-Cre expression domain showed that although it was expressed early enough to delete Vangl2 in cardiomyocyte progenitors [31], its expression was patchy in the distal outflow in our hands, and Vangl2 expression was maintained in these cells. Thus, these data are consistent with the idea that Vangl2 is required in undifferentiated cells, rather than differentiated derivatives of the SHF.
During outflow tract elongation in chickens, cells move from a proliferative pool within the dorsal pericardial wall into the distal outflow not as individual cells, but as a cohesive sheet [6]. This is similar to the movements of epithelial sheets in other organ systems [39], [40]. Although this mechanism of addition of cells to the outflow has not been confirmed in mammals, it seems likely that an analogous process takes place. Once they reach the region of the distal outflow, our data suggests the SHF-derived cells then acquire a more epithelial phenotype (i.e. robust polarised expression of E-cadherin) than they exhibited while they were in the mesothelium of the dorsal pericardial wall. Within this newly epithelialized tissue, Vangl2 signalling regulates the apical-basal polarised expression of a range of markers of stratified epithelial tissues, including Scrib and PKCζ [41], [42]. We see markedly abnormal distribution of these markers in the distal outflow tract wall of Vangl2flox/flox; Isl1-Cre embryos, with a reduced apical domain and expanded basolateral domain. Moreover, analysis of the position of MTOCs in the cells of the distal outflow tract suggests that planar polarisation of cells is also disturbed within this tissue. Thus, both apical-basal and planar cell polarity appear to be regulated by Vangl2 within the early outflow tract (Fig. 8 K,L).
We propose that the polarisation of the cells within the distal outflow tract and the consequent acquisition of epithelial phenotype is linked to the elongation of the outflow vessel. Specifically, we propose that the organisation of the cells into a pseudo-stratified epithelium ensures that the outflow tract wall lengthens rather than thickens. Epithelia are characterised by cells with strong lateral attachments (including E-cadherin-containing adherens junctions) that keep the cells in a sheet. Our data suggests that Vangl2 plays a key role in regulating planar polarity in the distal outflow wall, such that the cells are similarly oriented within the plane of the epithelium. When Vangl2 is lost from these cells in the distal outflow wall, cells are rotated relative to their neighbours, resulting in mis-positioning of the junctional complexes and disruption of the characteristic epithelial phenotype of the tissue (see Fig. 8 K-M for simplified cartoon). Our observation that Vangl2 also appears to be regulating the apical-basal positioning of markers, may add to this phenotype by further disrupting the positioning of cell junctions. Thus, Vangl2 appears to be essential for forming/maintaining the sheet-like structure of the cells that is necessary for epithelial tube formation. The thickened, shortened outflow tract seen in the absence of Vangl2 in some ways resembles the consequences of disrupted PCP signalling at gastrulation in vertebrate embryos, when convergence and extension movements narrow and lengthen the developing embryo (reviewed in [18]). Both processes likely involve junctional remodelling [40], however, the similarities in final-phenotype may be misleading as the SHF cells are added to the distal end of the lengthening outflow tract, whereas convergence and extension gastrulation movements occur intrinsically within a fixed pool of cells. Indeed, the process we describe does not seen to be directly analogous to any other mammalian organ system so far described. However, there are similarities with the described roles for PCP genes in tracheal tube lengthening in Drosophila [43] and Vang1 (the only worm vang/strabismus gene) specifically in C.elegans intestinal tube formation [44]. In both these cases, disruption of PCP signalling results in disorganisation of polarised markers and cell-cell relationships, and a shortened epithelial tube. During the early development of the outflow tract, undifferentiated SHF cells, expressing Isl1, move from the mesothelium of the dorsal pericardial wall into the outflow tract before differentiating to cardiomyocytes. This process happens prematurely in the Vangl2flox/flox; Is1-Cre mutants. Thus, the acquisition of the organised epithelial phenotype may be important both physically to create length within the tubular structure of the distal outflow, but also to prevent premature differentiation of the cells. Whether the latter contributes directly to the phenotype remains unclear. Interestingly, Wnt5a, an activator of PCP signalling, has been shown to be regulated by Tbx1 [45], one of the key transcription factors involved in maintaining SHF cells in a proliferative, undifferentiated state [10]. Thus, Vangl2 may be acting with these other factors in a network that regulates the addition of SHF cells to the lengthening outflow tract.
The link between a shortened outflow tract and double outlet right ventricle is well recognised [46], [47]. The on-going, regulated addition of cells from the SHF is crucial for the elongation of the vessel, a process that is required to position the proximal regions of the vessels so that they can align appropriately with the ventricular chambers. In the absence of Vangl2, the outflow tract thickens rather than lengthens. This shortened, thicker outflow tract is unable to align correctly with the ventricular chambers, resulting in double outlet right ventricle and ventricular septal defects (Fig. 8M). Whether this mechanism could explain cardiac alignment defects such as double outlet right ventricle in humans is the subject of on-going studies.
Disruption of Vangl2, either throughout the body or just in the SHF lineage, results in double outlet right ventricle and ventricular septal defects. Notably, we saw no abnormalities when Vangl2 was deleted in NCC, despite PCP signalling having been shown to play crucial roles in NCC migration in frogs and zebrafish [17]. Indeed, a recent study has shown that Vangl signalling is dispensable for NCC migration in mice [38], suggesting that NCC migration is regulated differently in mammals than in frogs, fish and birds. Similar outflow malformations to those we observe when Vangl2 is deleted specifically in the SHF lineage are observed in mice carrying mutations in other PCP genes including Dvl 1-3, Wnt5a, Wnt11 and Fz1/Fz2 [48], [49], [50], [51], [52]. Whilst there are likely to be multiple causes of double outlet right ventricle, the strong relationship between this abnormality and mutations in PCP pathway genes suggests that PCP signalling may be fundamental to the normal septation and alignment of the great arteries with the ventricular chambers. As well as ultimately developing double outlet right ventricle, Wnt11-/- mutants display abnormalities at earlier stages of heart development. These include a reduction in outflow tract length and perturbation in the cytoarchitecture of outflow tract cardiomyocytes [51]. TGFβ2 signalling was shown to be acting downstream of Wnt11 in the outflow myocardium, and Wnt11 null and Tgfβ2 null embryos showed abnormalities in apical-basal markers in the outflow wall at E11.5 [51]. Although earlier stages were not analysed, and thus a direct comparison with our study cannot be made, it is possible that TGFβ2, acting downstream of Wnt11 and Vangl2, might be involved in maintaining organisation of the distal outflow tract wall and thus regulate outflow tract lengthening. More recently, Sinha et al, [53] studied the abnormalities in outflow tract morphogenesis in Dvl2 mutants. They concluded that the defects resulted from abnormalities in the incorporation of SHF progenitors from the splanchnic mesoderm into the dorsal pericardial wall, prior to movement into the outflow vessel. Vangl2 is expressed in the dorsal pericardial wall, however despite close examination, we saw no abnormalities in this area. Sinha et al (2012; [53]) did not describe the phenotype of the cells within the distal outflow tract in the Dvl2 mutants, or examine markers of polarised cells in their embryos. Thus it is unclear whether the mechanism we describe could also be a component of the Dvl2 mutant phenotype. However, Wnt11 is expression is restricted to the outflow tract myocardium [51] suggesting that this might be a key factor in activating PCP and thereby Vangl2 signalling in the distal outflow tract. Thus, it seems likely that PCP signalling, via Vangl2 and Wnt11 (and/or Wnt5a), is playing an essential role in elongating the distal outflow tract, facilitating on-going cardiac morphogenesis.
Methods
Ethics statement
All animals were maintained and killed according to the requirements of the Animals (Scientific Procedures) Act 1986 of the UK Government. This work was approved by the Newcastle University Ethical Review Committee and conformed to Directive 2010/63/EU of the European Parliament.
Mouse strains and embryos
Loop-tail mice from the LPT/Le inbred strain were originally obtained from Professor Andrew Copp (UCL, London). Vangl2floxneo mice were created in partnership with Ozgene (Australia). The mice were subsequently crossed with FlpE [54] mice to generate Vangl2flox mice and then inter-crossed with ROSA-Stop-eYFP [55] mice to allow Cre-based lineage tracing. Cre driver lines, including Sox2-Cre [56], PGK-Cre [57], Isl1-Cre [58], Wnt1-Cre [59], Mlc2v-Cre [60], and Nkx2.5-Cre [30] were all intercrossed with the Vangl2flox line and ROSA-Stop-eYFP mice. All mice were maintained on the C57Bl/6 background (Charles River) and were backcrossed for a minimum of three generations. For all experiments, transgenic mice were compared with their wild type and heterozygote littermates. Mice were bred and embryos collected according to standard protocols [32].
Genotyping of Vangl2flox mice
Vangl2flox mice were genotyped using genomic DNA isolated from ear clips or limb buds using primers: forward: CCGCTGGCTTTCCTGCTGCTG; reverse: TCCTCGCCATCCCACCCTCG.
In situ hybridization
Embryos were dissected and fixed in 4% paraformaldehyde (PFA) in DEPC-PBS (phosphate buffered saline) overnight. The following day, the embryos were washed in PBS, dehydrated sequentially in 25%, 50% and 75% methanol in PBT (0.1% Tween 20 in PBS) on ice, and then stored at −20°C in 100% methanol until use. When required, embryos were rehydrated through the reverse methanol series as above and then equilibrated in PBT. The embryos were bleached in 6% hydrogen peroxide in PBT for 1 hour to inactivate endogenous peroxidase in the embryos, and washed three times in PBT. To improve the penetration of the probe into the embryo, they were treated with proteinase K (PK, 5 µg/ml) at RT for 7 minutes (in case of E10.5 embryos). Glycine (2 mg/ml) was added to stop the PK activity and the embryos were gently rocked for 5 minutes. After two washes in PBT, the embryos were refixed in 0.2% glutaraldehyde in 4% PFA, and then rocked for 20 minutes. 1 ml of prehybridization solution was added to the embryos in a 2 ml tube and they were incubated at 70°C for 2 hours. After discarding the prehybridization solution, 500 µl of hybridisation solution including the DIG-labeled RNA probe (1 µg/ml) was replaced and then incubated at 70°C overnight. The next day, the embryos were washed twice in salt solution I and II (Solution I, 50% formamide, 5x SSC, pH 4.5, 1% SDS; Solution II, 50% formamide, 2x SSC, pH 4.5) at 70°C for 30 minutes, respectively. Embryos were washed three times for 5 minutes at RT temperature in freshly made MABT and non-specific antigens blocked by incubating in a 10% blocking solution (Roche) in MABT for 1 hour. Anti-DIG antibody (Roche) was added to 1% blocking solution/MABT at a concentration of 1∶5000 and was left to pre-absorb at 4°C for 1 hour. 500 µl of the antibody solution was added to each embryo and they were left at 4°C for two nights with gentle rocking to allow complete penetration of the antibody. After this incubation, embryos were washed three times for 5 minutes in TBST then 5 times of 1 hour washes in TBST at RT. Embryos were then given 3 times of 10 minutes washes in NTMT to prepare them for development. Embryos were transferred to glass bottles and 3ml of NBT/BCIP (1, 4-nitro blue tetrazolium chloride/5-bromo-4-chloro-3-indoyl-phosphate) added to each at a concentration of 18 µl/ml of NTMT. Embryos were left to develop in the dark until the desired level of staining was achieved. Once the reaction was completed, the embryos were washed in PBT twice for 5 minutes, and stored in the dark in PBT containing 0.48 µg/ml of thymerisol to prevent fungal growth.
RT-PCR
Total RNA extraction from embryonic tissue was carried out using 1 ml Trizol-Reagent (Ambion) per sample, according to the manufacturer's instructions. Samples were quantified via spectrophotometry, and cDNA generated, using 1 µg of total RNA as a template, with superscript III reverse transcriptase (Life technologies). PCR was carried out using the following primers: TGAGGGCCTCTTCATCTCC, ACCAATAACTCCACGGG.
Wax embedding and haematoxylin and eosin staining
Following dissection at the appropriate stage of development, embryos were washed in PBS, and then fixed by immersion in 4% paraformaldehyde in PBS at 4°C for 1 to 3 nights dependent on their age. Embryos were subsequently dehydrated in ethanol and processed for wax sectioning. Sections were cut at 8 µm using a rotary microtome (Leica). For haemotoxylin and eosin staining, slides were de-waxed with two 10 minute washes of Histoclear and were hydrated to water through an ethanol/H20 gradient (100%, 90% 70% and 50%). Slides were placed in Ehrlich haematoxylin (RA Lamb) for 10 minutes then were transferred into a trough of running tap water. The slides were left until the sections changed colour from purple to blue. The sections were differentiated by dipping in acid alcohol (1% HCl in 70% ethanol) for 10–30 seconds, and then were placed back into tap water until the blue colour was restored. When an acceptable intensity of haemotoxylin stain was achieved, the slides were transferred into 1% aqueous eosin for 5 minutes, rinsed in tap water, then dehydrated through the same ethanol gradient, before washing twice in Histoclear and mounting in Histomount (National Diagnostics).
Production of the Vangl2 antibody
The Vangl2 antibody, produced by C. Dean, was raised in rabbit against the following Vangl2 specific peptide: CLAKKVSGFKVYSLGEENST by 21st Century Biochemicals, MA, USA and validated by western blot on lysate from HEK293 cells transfected with a Vangl2-GFP construct. A band representing the GFP-tagged construct was detected just above the 75KDa marker using either the Vangl2 antibody or an anti-GFP antibody.
Immunohistochemistry
Slides were de-waxed with Histoclear and rehydrated through a series of ethanol washes. Following washes in PBS, antigen retrieval was performed by boiling slides in citrate buffer (0.01 mol/L) for 10 minutes. Samples were blocked in 10% FCS and then incubated either overnight at 4°C, or at room temperature for 2 hours with the following antibodies: E-cadherin, β-catenin, N-Cadherin (BD Transduction Laboratories), fibronectin, Scrib, PKCζ (Santa Cruz), Isl1, MF20 (Developmental studies Hybridoma Bank, University of Iowa), GFP, alpha smooth muscle actin (Abcam), gamma tubulin, laminin (Sigma), cardiac troponin I (HyTest), desmin (Millipore). For immunofluorescence, samples were incubated at room temperature for two hours, with secondary antibodies conjugated to either Alexa 488 or Alexa 594 (Life Technologies). Fluorescent slides were washed then mounted with Vectashield Mounting medium with DAPI (Vector Labs). For non fluorescent staining, samples were incubated with biotinylated secondary antibodies for 1 hour, then with AB complex (Vector labs) for a further hour. Slides stained with DAB were washed then counter-stained with 5% methyl green. After dehydration in 100% butanol and Histoclear, slides were mounted using Histomount.
Quantification of cell polarity
Cells were stained with the γ–tubulin antibody to identify the microtubule organising centre (MTOC). The orientation of the cell was defined by the angle between the most apical extent of the cell, the centre of the cell and the MTOC, and was measured using the angle tool in ImageJ. MTOCs lying proximally relative to the apex were considered to have an obtuse angle, and were transformed as such. Angles were converted to radians and plotted using the rose plot function in MATLAB. To analyse the distribution of MTOCs in control and mutant outflow tracts, eight sectors of possible MTOC cell position were defined (0–44°, 45–89°… 315–359°) and the distribution of MTOCs within these sectors compared by Chi-Square (IBM, SPSS statistics, version 21).
β-gal staining
Cells with an active lacZ gene in embryos carrying both the Wnt1-Cre and ROSA26R constructs stain blue when treated with X-Gal. Embryos were washed twice in PBS and fixed in a solution containing 0.1 M phosphate buffer, 2% PFA, 5 mM EGTA (pH 8.0), 0.2% glutaraldehyde and 2 mM MgCl2. They were washed twice in wash buffer (0.1 M phosphate buffer, 0.01% Na-deoxycholate, 0.02% Nonidet-P40, 2 mM MgCl2) and X-Gal stained at 37°C wrapped in aluminium foil overnight. X-Gal solution contains 10 mM K-ferrocyanide, 10 mM K-ferricyanide and 1 mg/ml X-Gal in wash buffer. Stock X-Gal powder is dissolved in dimethylformamide before adding to the staining solution. The next day, after rinsing in PBS, the embryos were fixed in 4% PFA and embedded in wax as described above.
Western blotting
Tissue samples from embryos were lysed with 500 µl 1X laemmli buffer (2% SDS, 5% betamercaptoethanol), 10% glycerol, 0.05% w/v bromophenol blue, 0.0625M Tris-HCl pH 6.8) and run on pre-cast 10% poly-acrylamide gels (Biorad). Samples were transferred to PVDF (ImmobilonP Millipore) in ice cold transfer buffer (48 Mm Tris-HCl pH 8, 39 mM glycine, 0.04% SDS, 20% methanol) for 1 hour at 4°C. Membranes were washed in TBST (2.4% w/v Trizma hydrochloride, 8% w/v sodium chloride at pH 7.6; 0.1% Tween-20) then blocked in 5% milk/TBST at room temperature for 1 hour. The membrane was incubated with primary antibody (Vangl2 1∶2500/GAPDH 1∶25000 in 5% milk/TBST) overnight at 4°C, washed then incubated with secondary antibody (1∶2500, Dako) for 1 hour at room temperature. Membranes were washed then developed with ECL substrate (SuperSignal West Dura, Thermo Scientific) on Amersham Hyperfilm ECL (GE healthcare).
Graphics
Images were manipulated in Photoshop CS3 (Adobe). Diagrams were created using CorelDRAW X5 (Corel).
Supporting Information
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Štítky
Genetika Reprodukčná medicínaČlánok vyšiel v časopise
PLOS Genetics
2014 Číslo 12
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