FIGURE SUMMARY
Title

Nkx genes are essential for maintenance of ventricular identity

Authors
Targoff, K.L., Colombo, S., George, V., Schell, T., Kim, S.H., Solnica-Krezel, L., and Yelon, D.
Source
Full text @ Development

Mutation of nkx2.5 disrupts cardiac morphogenesis. (A,B) Lateral views of live zebrafish embryos, anterior to the left, at 52 hpf. Other than cardiac defects and pericardial edema, the nkx2.5 mutant embryo (B) appears morphologically normal. (C,D) Lateral views of live embryos, anterior to the top, at 52 hpf. In contrast to the wild-type heart (C), the nkx2.5 mutant heart (D) is unlooped and has striking defects in both ventricular and atrial morphology. (E,F) MF20/S46 immunofluorescence distinguishes ventricular myocardium (red) from atrial myocardium (yellow). Frontal views, anterior to the top, at 52 hpf. In comparison to the wild-type heart (E), the nkx2.5 mutant heart (F) has a diminutive ventricle and an enlarged atrium. (G-L) In situ hybridization depicts expression of myl7 (G,H), vmhc (I,J) and amhc (K,L) in wild-type (G,I,K) and nkx2.5 mutant (H,J,L) embryos. Dorsal views, anterior to the top, at 26 hpf. (G,H) nkx2.5 mutant embryos exhibit subtle defects in heart tube extension, including a broad inflow region and a compact outflow region. In nkx2.5 mutants, the ventricular portion of the heart tube is abnormally short and wide (I,J) and the atrial portion of the heart tube has a splayed appearance (K,L).

Increased atrial and decreased ventricular cell numbers are first evident in nkx2.5 mutants following heart tube extension. (A-F) Immunofluorescence indicates expression of the transgene Tg(-5.1myl7:nDsRed2) (red) in both cardiac chambers facilitating cardiomyocyte counting at 26 hpf (A,B), 36 hpf (C,D) and 52 hpf (E,F). Atria are labeled with the anti-Amhc antibody S46 (green). (G-I) Bar graphs indicate numbers of atrial and ventricular cardiomyocyte nuclei, as well as the total number of cardiomyocytes; mean and s.e.m. of each data set are shown, and asterisks indicate statistically significant differences from wild type (P<0.001). (G) At 26 hpf, we find no statistically significant difference in cell numbers in wild-type (n=20) and nkx2.5 mutant (n=7) embryos. (H) At 36 hpf, comparison of wild-type (n=16) and nkx2.5 mutant (n=10) embryos reveals an increase in atrial cell number and a decrease in ventricular cell number in nkx2.5 mutants. (I) At 52 hpf, comparison of wild-type (n=16) and nkx2.5 mutant (n=11) embryos reveals an increase in atrial cell number and a decrease in ventricular cell number in nkx2.5 mutants.

Loss of nkx2.7 function in nkx2.5 mutants yields a more prominent ventricular deficiency. (A-F) Frontal views, anterior to the top, of MF20/S46 immunofluorescence, which distinguishes ventricular myocardium (red) from atrial myocardium (yellow), at 52 hpf. In comparison to wild type (A), injection of anti-nkx2.7 MO (D) causes subtle abnormalities in chamber morphology. (B,E) In the nkx2.5 heterozygote, mild atrial enlargement is observed following injection of anti-nkx2.7 MO. (C,F) Injection of anti-nkx2.7 MO into nkx2.5 mutants yields severe loss of ventricular tissue and dramatic expansion of Amhc (S46, yellow) throughout the heart. Arrow indicates ventricular remnant that includes Amhc localization.

nkx2.5-/-;nkx2.7-/- double mutant demonstrates the synergistic requirement for Nkx genes in maintenance of ventricular identity. (A,B) Lateral views of live embryos, anterior to the left, at 52 hpf. General embryonic morphology appears similar in wild-type (A) and nkx2.7 mutant (B) embryos. (C,D) Lateral views of live embryos, anterior to the top, at 52 hpf. The nkx2.7 mutant heart (D) exhibits subtle defects in ventricular and atrial morphology. (E-I) Frontal views, anterior to the top, of MF20/S46 immunofluorescence, which distinguishes ventricular myocardium (red) from atrial myocardium (yellow), at 52 hpf. In comparison to wild-type embryos (E), nkx2.7 mutants (F) exhibit subtle abnormalities in chamber size and shape whereas nkx2.5 mutants (G) demonstrate an impressive size discrepancy between the ventricular and atrial chambers. (H) In the nkx2.5 mutant, loss of a single allele of nkx2.7 leads to increased localization of Amhc (S46, yellow) within the ventricle. (I) Exacerbation of the ventricular deficiency is evident in the nkx2.5-/-;nkx2.7-/- mutants, and Amhc is present throughout the entire cardiac structure.

Loss of nkx2.7 function in nkx2.5 mutants exacerbates defects during heart tube extension. (A-H) In situ hybridization depicts expression of amhc (A,B,E,F) and vmhc (C,D,G,H) in wild-type embryos (A,C), nkx2.5 mutants (B,D), wild-type embryos injected with anti-nkx2.7 MO (E,G) and Nkx-deficient embryos (F,H). Dorsal views, anterior to the top, at 26 hpf. The nkx2.5 mutant embryos exhibit subtle defects in heart tube extension, including a broader atrial region (A,B) and a slightly shorter ventricular region (C,D). Following MO injection, wild-type embryos demonstrate a spread of atrial cells and a compact coalescence of the ventricular cells (E,G). MO injection into nkx2.5 mutants leads to an exacerbated phenotype with a sprawling, widened atrial portion and a stunted ventricular portion of the heart tube (F,H).

Gradual elimination of ventricular gene expression and expansion of atrial gene expression in the Nkx-deficient heart. In situ hybridization illustrates expression of amhc (A,B,E,F,I,J,M,N) and vmhc (C,D,G,H,K,L,O,P) in wild-type embryos (A,C,I,K), nkx2.5 mutants (B,D,J,L), wild-type embryos injected with anti-nkx2.7 MO (E,G,M,O) and Nkx-deficient embryos (F,H,N,P). (A-H) Dorsal views, anterior to the bottom, at 36 hpf. The nkx2.5 mutants display a dilated atrium (A,B) and shortened ventricle (C,D). Following MO injection, wild-type embryos demonstrate a swollen atrium and widened ventricle (E,G). In nkx2.5 mutants, MO injection leads to distinct expansion of amhc and fading of vmhc in the ventricular remnant (F,H; arrows). (I-P) Ventral views, anterior to the top, at 52 hpf. Phenotypes are exacerbated at 52 hpf, both in terms of morphological defects and expression pattern changes. Most dramatically, in the Nkx-deficient embryo, amhc is expressed throughout the entire heart whereas vmhc expression is effectively abolished (N,P).

Dynamic expression patterns highlight gradual transitions in cardiomyocyte identity. Two-color fluorescence in situ hybridization facilitates sensitive detection of amhc (green) and vmhc (red) expression. Confocal projections of fixed, dissected wild-type (A-C,J-L), nkx2.5 mutant (D-F,M-O) and Nkx-deficient hearts (G-I,P-R); ventral views, anterior to the top. (A-I) At 36 hpf, ectopic amhc-expressing cells are found in the ventricle in the nkx2.5 mutant heart (D-F; arrowhead) and, more extensively, in the Nkx-deficient heart (G-I; arrowhead). (J-R) At 52 hpf, ectopic amhc-expressing cells are visualized in the dramatically diminished nkx2.5 mutant ventricle (M-O; arrowhead) whereas only a tuft of residual vmhc expression remains at the pole of the Nkx-deficient heart (P-R; arrowhead).

EXPRESSION / LABELING:
Genes:
Fish:
Knockdown Reagent:
Anatomical Terms:
Stage Range: Prim-25 to Long-pec

nkx2.5 and nkx2.7 work together to maintain vmhc expression and to limit amhc expression. (A-I) Fluorescence in situ hybridization depicts expression patterns of amhc (green) and vmhc (red) in wild-type (A-C), nkx2.5 mutant (D-F) and nkx2.5-/-;nkx2.7-/- double mutant (G-I) hearts at 52 hpf. Compared with robust expression of vmhc in both the wild-type (B) and nkx2.5 mutant (E) hearts, encroachment of ectopic amhc expression is demonstrated alongside dwindling vmhc expression in the ventricular remnant of the nkx2.5-/-;nkx2.7-/- mutant heart (G-I).

Ventricular-to-atrial transformation occurs in the absence of Nkx gene function. Confocal projections of live zebrafish hearts carrying Tg(myl7:kaede) are depicted immediately following photoconversion at 26-30 hpf (A-C,G-I,M-O) and after later visualization at 48-52 hpf (D-F,J-L,P-R); arterial pole to the top. Green fluorescence of Kaede (A,G,M) is converted to red fluorescence (B,H,N) following UV exposure of the region of interest; merged views (C,I,O) indicate that labeled cells are at the arterial pole of the heart tube. At later time points, retained red fluorescence (E,K,Q) is visualized together with the green Kaede (D,J,P) that is continually produced by the transgene; merged views (F,L,R) indicate the locations of the labeled cells. (A-F) In wild-type embryos, labeling of ventricular cells near the arterial pole of the heart tube (A-C) yields labeled cells within the ventricular chamber at 48 hpf (D-F) (n=17/17). (G-L) By contrast, comparable photoconversion of ventricular cardiomyocytes at the arterial pole of the nkx2.5 mutant heart tube (G-I) generates labeled cells both within the diminutive ventricular chamber and expanding into the atrial chamber (J-L, arrowhead in L) (n=10/12). (M-R) In Nkx-deficient embryos, labeled cells from the vmhc-expressing portion (supplementary materialFig. S9N) of the heart tube (M-O) are later detected within the single, amhc-expressing (supplementary material Fig. S9P) chamber of the heart (P-R) (n=2/2).

EXPRESSION / LABELING:
Gene:
Fish:
Knockdown Reagent:
Anatomical Term:
Stage Range: Prim-5 to Long-pec

Normal patterning of anterior lateral plate mesoderm in nkx2.5 mutant embryos.
(A-D) In situ hybridization demonstrates expression of scl (A,B) and hand2 (C,D) in wild-type (A,C) and nkx2.5 mutant (B,D) embryos at the 8 somite stage. Dorsal views, anterior to the top. Gene expression patterns appear normal in nkx2.5 mutants; no expansion or reduction of heart field size is evident.

Normal differentiation and fusion of bilateral cardiac precursor populations in nkx2.5 mutant and nkx2.5-/-;nkx2.7-/- double mutant embryos. (A-F) In situ hybridization depicts expression of amhc (A-C) and vmhc (D-F) in wildtype (A,D), nkx2.5 mutant (B,E), and nkx2.5-/-;nkx2.7-/- double mutant (C,F) embryos. Dorsal views, anterior to the top, at the 22 somite stage. Gene expression patterns appear normal in nkx2.5 mutant and nkx2.5-/-;nkx2.7-/- double mutant embryos; no expansion or reduction of atrial or ventricular precursor populations is evident.

Expression of irx4a is progressively downregulated with increased loss of Nkx gene dosage.
(A-C) In situ hybridization depicts expression of irx4a in wild-type (A), nkx2.5 mutant (B), and nkx2.5-/-;nkx2.7-/- double mutant (C) embryos. Dorsal views, anterior to the top, at 26 hpf. Ventricular expression of irx4a (arrows) is diminished in nkx2.5 mutants and absent in nkx2.5-/-;nkx2.7-/- double mutants. Expression of irx4a is also visible in bilateral neurons of the lateral hindbrain.

Expression of hey2 is progressively downregulated with increased loss of Nkx gene dosage.
(A-E) In situ hybridization depicts expression of hey2 at 26 hpf. Lateral views, anterior to the left. hey2 expression in the ventricle (arrows) is evident in wild-type (A) and nkx2.7 mutant (B) embryos. However, hey2 expression is diminished in nkx2.5 mutant (C) and nkx2.5-/-;nkx2.7+/- mutant (D) embryos and is absent in nkx2.5-/-;nkx2.7-/- mutant embryos (E). Expression of hey2 is also visible in the diencephalon.

Mosaic labeling tracks cardiomyocyte behavior. Confocal projections of mosaic hearts in live zebrafish embryos. Mosaic labeling was performed by injecting Tg(myl7:EGFP) plasmid into nkx2.5 mutant embryos and their wild-type siblings, both of which carried Tg(myl7:DsRedt4). Embryos with 2-6 GFPpositive cells were followed from 26 to 52 hpf, allowing for detailed analysis of cell behaviors, including division, appearance, and disappearance of cardiomyocytes. (A-F) Representative examples of observed cell behavior scenarios. The observed frequency of occurrence of each scenario in wild-type and nkx2.5 mutant embryos is provided in Table S1. (A,B) Most cells remained stable during the tracking period; as shown in this example, 4 GFP-positive cells in the atrium of a nkx2.5 mutant heart exhibit stable morphology and orientation. (C,D) In some embryos, new GFP-positive cells appeared during the tracking period; in this example, a new GFP-positive cell (yellow arrow in D) appears in a wild-type atrium. Given the distance between the new GFPpositive cardiomyocyte and the 4 originally labeled cells (yellow arrowheads in C and D), the new cell is not likely to be the product of cell division. Instead, newly appearing cells most likely reflect delayed initiation of myl7 expression in late-differentiating, SHFderived cardiomyocytes (de Pater et al., 2009; Hami et al., 2011; Lazic and Scott, 2011; Zhou et al., 2011). (E,F) Cell division was occasionally observed; in this example, a single cardiomyocyte (yellow arrow in E) in a wild-type embryo gives rise to two daughter cells (yellow arrows in F).

Developmental timing assay indicates late-differentiating cells added to the arterial pole of the nkx2.5 mutant heart.
Confocal projections of hearts in live wild-type (A-D) and nkx2.5 mutant (E-H) embryos expressing Tg(myl7:EGFP) (A,E) and Tg(-5.1myl7:nDsRed2) (B,D,F,H). Lateral views, arterial pole to the top, at 52 hpf. (D,H) White dots outline the morphology of the Tg(myl7:EGFP)-expressing ventricle and outflow tract. (A-D) In the wild-type heart, the late-differentiating cardiomyocyte population exhibits green, but not red, fluorescence, due to the delay in expression of Tg(-5.1myl7:nDsRed2), in comparison with expression of Tg(myl7:EGFP), at the arterial pole (de Pater et al., 2009). (F-H) Similarly, in the nkx2.5 mutant heart, cardiomyocytes expressing Tg(myl7:EGFP), but not Tg(-5.1myl7:nDsRed2), are present at the arterial pole.

Expression of ltbp3 is downregulated in nkx2.5 mutant and nkx2.5-/-;nkx2.7-/- double mutant embryos.
(A-E) In situ hybridization depicts expression of ltbp3 at 26 hpf. Dorsal views, anterior to the top. ltbp3 expression is visible at the arterial pole in wild-type (A) and nkx2.7 mutant (B) embryos. However, ltbp3 expression is reduced in nkx2.5 mutant embryos (C) and is absent in nkx2.5-/-;nkx2.7+/- (D) and nkx2.5-/-;nkx2.7-/- (E) mutant embryos.

Gene expression patterns indicate ventricular and atrial territories.
In situ hybridization illustrates expression patterns of amhc (A,D,G,J,M,P), vmhc (B,E,H,K,N,Q), and myl7 (C,F,I,L,O,R) at 26 (A-C,G-I,M-O) and 52 hpf (D-F,J-L,P-R). Representative examples of wild-type (A-F), nkx2.5 mutant (G-L) and Nkx-deficient (MR) embryos clarify the territories generally considered to be expressing vmhc or amhc when conducting and interpreting photoconversion experiments (Fig. 9).

Acknowledgments
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