The Drosophila homolog of vertebrate Islet1 is a key component in early cardiogenesis

doi:10.1242/dev.022533

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First published online 15 December 2008
doi: 10.1242/dev.022533

Development 136, 317-326 (2009)
Published by The Company of Biologists 2009

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The Drosophila homolog of vertebrate Islet1 is a key component in early cardiogenesis

Tabea Mann¹, Rolf Bodmer² and Petra Pandur¹^,*

¹ Institute for Biochemistry and Molecular Biology, University of Ulm, Albert-Einstein-Allee 11, 89081 Ulm, Germany.
² Burnham Institute for Medical Research, Center for Neuroscience, Aging and Stem Cell Research, Development and Aging Program, 10901 North Torrey Pines Road, La Jolla, CA 92037, USA.

^* Author for correspondence (e-mail: petra.pandur{at}uni-ulm.de)

Accepted 6 November 2008

SUMMARY

TOP
SUMMARY
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

In mouse, the LIM-homeodomain transcription factor Islet1 (Isl1)has been shown to demarcate a separate cardiac cell population thatis essential for the formation of the right ventricle and theoutflow tract of the heart. Whether Isl1 plays a crucial rolein the early regulatory network of transcription factors thatestablishes a cardiac fate in mesodermal cells has not beenfully resolved. We have analyzed the role of the Drosophilahomolog of Isl1, tailup (tup), in cardiac specification andformation of the dorsal vessel. The early expression of Tupin the cardiac mesoderm suggests that Tup functions in cardiac specification.Indeed, tup mutants are characterized by a reduction of theessential early cardiac transcription factors Tin, Pnr and Dorsocross1-3(Doc). Conversely, Tup expression depends on each of these cardiacfactors, as well as on the early inductive signals Dpp and Wg.Genetic interactions show that tup cooperates with tin, pnrand Doc in heart cell specification. Germ layer-specific loss-of-function andrescue experiments reveal that Tup also functions in the ectodermto regulate cardiogenesis and implicate the involvement of different LIM-domain-interactingproteins in the mesoderm and ectoderm. Gain-of-function analysesfor tup and pnr suggest that a proper balance of these factorsis also required for the specification of Eve-expressing pericardialcells. Since tup is required for proper cardiogenesis in aninvertebrate organism, we believe it is appropriate to include tup/Isl1in the core set of ancestral cardiac transcription factors thatgovern a cardiac fate.

Key words: Drosophila, Cardiogenesis, Islet1, Tailup, Second heart field

INTRODUCTION

TOP
SUMMARY
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

In our effort to decipher the molecular network that determinesa cardiac fate, we attempt to identify all the key players inthis process. Some time ago, the LIM-homeodomain transcriptionfactor Islet1 (Isl1), known for its role in neural development,was introduced as a novel gene with a function in mouse heartdevelopment (Korzh et al., 1993; Pfaff et al., 1996; Thor andThomas, 1997; Cai et al., 2003). Initial analyses of the murineIsl1 expression pattern, combined with the missing right ventricleand outflow tract of the heart in Isl1 knockout mouse embryos,suggested that Isl1 demarcates a separate cardiac lineage, alsocalled the second heart field (Cai et al., 2003) (reviewed byBuckingham et al., 2005; Abu-Issa and Kirby, 2007). However,in vitro studies in cell culture systems and analysis of Xenopus Isl1implicate that Isl1 is part of the early transcriptional networkthat establishes a cardiac fate in mesodermal cells (reviewedby Anton et al., 2007; Brade et al., 2007). Here, we took advantageof the Drosophila model to genetically determine whether tailup(tup), the fly homolog of Isl1, is required for the specificationof heart precursor cells.

The Drosophila heart, although a simple tube, has become a paradigmof studying complex genetic interactions that determine cellfate. Two major cell types comprise the fly heart, which formsat the dorsal midline of the embryo. The contractile myocardialcells form the lumen of the dorsal vessel. The six myocardialcells per hemisegment are flanked by a group of pericardialcells that are needed for normal heart function. During embryogenesis,two of the six myocardial cells further differentiate into specializedmyocardial cells, the ostia, which serve as inflow tracts inthe posterior heart portion of the fly. Heart development inDrosophila is initiated in the dorsal mesoderm when a particulargroup of cells in each hemisegment receives input from the ectodermalgrowth factors Wingless (Wg) and Decapentaplegic (Dpp) (Wu etal., 1995; Frasch, 1995; Park et al., 1996). These signalingpathways induce in Tinman (Tin)-positive mesodermal cells acomplex network of transcription factors that distinguishes thecardiac mesoderm from the adjacent visceral mesoderm and dorsalsomatic muscles (Frasch, 1995; Riechmann et al., 1997; Lee andFrasch, 2000; Lockwood and Bodmer, 2002; Jagla et al., 2002).In addition to the homeobox transcription factor tin (Nkx2.5), earlyspecification requires the function of the T-box factors Dorsocross1-3(herein referred to as Doc) and of the GATA factor pannier (pnr) (Gajewskiet al., 1999; Alvarez et al., 2003; Klinedinst and Bodmer, 2003; Reimand Frasch, 2005). Once cardiac specification has taken place,tin, Doc and pnr cross-regulate each other to maintain theirexpression and to initiate the differentiation of the cardiaccells (reviewed by Zaffran and Frasch, 2002; Qian et al., 2008).The latter requires additional transcription factors, includingthe Tbx20-related gene neuromancer (nmr1 and nmr2; also knownas H15 and mid, respectively), the COUP-TFII-related gene sevenup (svp), and the homeobox gene ladybird (lb), which are involvedin regulating the diversity of myocardial and pericardial cellfates (Miskolczi-McCallum et al., 2005; Qian et al., 2005; Reimet al., 2005; Lo and Frasch, 2001; Jagla et al., 1997; Jaglaet al., 2002). Most of these transcription factors have a fairlydynamic expression pattern during heart development, which suggeststhat their specific function in cardiogenesis can vary dependingon the cellular context. For example, tin and Doc initiallycooperate to properly specify cardiac progenitors (Reim and Frasch,2005). However, during the differentiation of myocardial cells,tin represses Doc genes in four out of the six myocardial cellsin each hemisegment, thereby restricting Doc expression to thetwo Tin-negative cells that form the ostia in segments A2 to A7(Zaffran et al., 2006).

A phenotypic characterization of tup mutants has shown that tupplays an important role in Drosophila heart and hematopoieticorgan formation (Tao et al., 2007). However, these analyses,which included a description of the cardiac expression patternof Tup, were restricted to stages well past the time when cardiacspecification occurs. Hence, the question has remained whethertup is required for the proper specification of heart cells.

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Fig. 1. Tup expression during cardiogenesis in wild-type Drosophila embryos. (A) At stage 10, Tup is expressed in a broad domain in the dorsal ectoderm (arrowhead). The expression in the amnioserosa (as) persists throughout embryogenesis. (B) Double labeling for Wg protein and tup RNA confirms the ectodermal expression of tup. (C) At mid-stage 11, Tup starts to be expressed in the cardiac mesoderm in $~$ 10 small clusters of cells (arrowheads). (D) These clusters are also positive for Eve (arrowheads). (E) By late stage 11, Tup is co-expressed with Tin throughout the cardiac mesoderm (arrowheads). (F-H) Tup is expressed in all six myocardial cells (arrowheads) and in the Tin-positive pericardial cells (arrows in H). Arrowheads in H point to the two Tin-negative, Tup-positive myocardial cells. (I) Tup is expressed in all Odd-positive pericardial cells (arrows) and in a subset of Odd-expressing cells of the lymph glands (lg). (J) tup RNA expression in myocardial Dmef2-expressing cells matches Tup protein localization (arrowheads), as seen in G. Except for H and I, which are dorsal views of stage 15 embryos, all images are lateral views. Anterior is to the left. WT, wild type.

Here, we present a detailed study of Tup expression and functionduring cardiogenesis and show that tup is indeed required forthe specification of a cardiac fate. Analyses of genetic interactionsestablish tup as a crucial factor that cooperates with tin,pnr and Doc during cardiogenesis. Germ layer-specific inhibitionof Tup function shows that ectodermal Tup is also required fornormal Tin expression at early stages. Rescue experiments suggestthat there might be a different set of mesodermal and ectodermalfactors with which Tup can interact through its LIM domains.Cell-specific inhibition of Tup function shows that Tup is requiredto maintain expression of Odd in pericardial cells. Overexpression experimentsshow that a balance of Tup and Pnr is required for the correct specificationof Eve-expressing cell clusters. Taken together, these findings placetup as a crucial factor in the early cardiac transcriptional network.

MATERIALS AND METHODS

TOP
SUMMARY
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Drosophila stocks and crosses
The following mutant fly stocks were used: tup^isl-1 [isl^37Aa(Thor and Thomas, 1997], pnr^VX6, wg^CX4, dpp^d6, Df(2L)OD15 (allfrom The Bloomington Stock Center), tin³⁴⁶ (Azpiazu and Frasch,1993) and Df(3L)DocA (Reim et al., 2003). The tup^isl-1, wg^CX4and the Df(2L)OD15 stocks were rebalanced with CyO, wg-lacZ,and the pnr^VX6 stock was rebalanced with TM3, ftz-lacZ to identifyhomozygous mutant embryos. CantonS served as a wild-type stock. Analysisof cuticles of tup^isl-1/CyO embryos (n=415) showed that 19%of the homozygous tup mutants (n=104) had an obvious germ bandretraction phenotype. These embryos were not included in ouranalyses. For the genetic interactions, embryos that were singleor double heterozygous for the investigated allele(s) were selectedbased on the lack of staining for β-galactosidase activity presenton the corresponding balancer chromosomes. Statistical computingwas performed using R (www.r-project.org). The following Gal4and UAS lines were used: twi-Gal4 (Greig and Akam, 1993), 69B-Gal4(Brand and Perrimon, 1993), Dot-Gal4 (Kimbrell et al., 2002),tinC ${Delta}$ 4-Gal4 (Lo and Frasch, 2001), UAS-tup, UAS-tup ${Delta}$ HD (Thor andThomas, 1997; O'Keefe et al., 1998), UAS-tup ${Delta}$ LIM (Biryukova andHeitzler, 2005), UAS-pnrD4 (Haenlin et al., 1997) and UAS-tin (Ranganayakuluet al., 1998). For co-overexpression of UAS-tup and UAS-pnrD4,the individual UAS constructs were recombined on the third chromosome.The UAS-tin;UAS-tup stock was generated by standard genetic crossings.

Immunohistochemistry and in situ hybridization
Antibody staining (single and double labeling) was performedessentially as described (Qian et al., 2005; Liu et al., 2006).Primary antibodies were detected with a Cy3-conjugated AffiniPuredonkey anti-rabbit IgG (H+L) (1:200) (Dianova, Hamburg, Germany).If amplification of the signal was necessary, biotinylated secondaryantibodies were used (1:200) in combination with the TyramideSignal Amplification System (Perkin Elmer) and dichlorotriazinylaminofluorescein (1:200) (Dianova). Embryos were mounted in Vectashield(Vector Laboratories). Embryos from single immunostainings were analyzedusing Olympus BX60 (Olympus, Hamburg, Germany) or Keyence BZ-8000K epifluorescencemicroscopes, with the image-analyzing software BZ-Analyzer (Keyence,Neu-Isenburg, Germany). Embryos from double immunostainingswere analyzed using a Leica TCS SP confocal microscope. Primaryantibodies were used at the following dilutions: mouse anti-chickenIsl1 (Tup), 1:50 with TSA [Developmental Studies Hybridoma Bank(DSHB)]; rabbit anti-Dmef2, 1:2000 (Lilly et al., 1995); rabbit anti-Tin,1:50 (Venkatesh et al., 2000); mouse anti-Pericardin (EC11),1:10 with TSA (DSHB); rabbit anti-Eve, 1:3000 (Frasch et al., 1987);rabbit anti-Odd, 1:100 (Ward and Skeath, 2000); and mouse anti-Pnr,1:400 with TSA (Herranz and Morata, 2001). Fluorescent in situhybridization for dpp was performed essentially as described (Klinedinstand Bodmer, 2003). Double fluorescent in situ hybridizationand immunostaining was adapted from Knirr et al. (Knirr et al., 1999).The digoxigenin-labeled dpp and pnr in situ probes were generatedusing the DIG RNA Labeling Mix from Roche (Mannheim, Germany).

RESULTS

TOP
SUMMARY
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Expression pattern of Tup during dorsal vessel development
Tup protein, as detected by a monoclonal mouse antibody againstchicken Isl1, was observed in a broad domain along the dorsalside of the Drosophila embryo at stage 10, within the ectodermallayer (Fig. 1A). This expression pattern is reminiscent of theexpression domain of ectodermal Dpp, as well as of those ofTin (mesoderm) and Pnr (initially only in the ectoderm), two transcriptionfactors that are crucial for proper cardiac specification. Doublelabeling for tup transcripts and Wg protein demonstrated more clearlythe ectodermal expression of tup (Fig. 1B). Double immunostainingsfor Tup and Tin were performed to identify Tup-positive cardiaccells within this broad domain. This analysis revealed thatTup expression in the cardiac mesoderm initiates at mid-stage11, when Tin becomes restricted to the dorsal-most mesoderm,in $~$ 10 clusters, each consisting of $~$ 2 cells (Fig. 1C). Cellsof the Tup clusters co-expressed Eve and therefore belong tothe pericardial cell lineage (Fig. 1D). By late stage 11, Tupexpression expanded within the Tin-expressing cardiac mesoderm(Fig. 1E) and continued in all myocardial cells during embryogenesis (Fig. 1F-I) (Taoet al., 2007). We also detected Tup in at least two of the Tin-positivepericardial cells and in all four Odd-expressing pericardialcells in each hemisegment (Fig. 1G-I). In the lymph glands,Tup was only expressed in some of the Odd-positive cells (Fig. 1I).tup transcripts were also present in the cytoplasm of the Dmef2(Mef2)-positive myocardial cells, demonstrating that the expressionpatterns of tup RNA and Tup protein were identical (Fig. 1J).Consistent with its function in amnioserosa development, Tup wasalso detected in this tissue. Here, we focus on the role oftup in heart development and our analysis demonstrates thatthe observed heart phenotype is not primarily an effect of adefect in germ band retraction.

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Fig. 2. Heart phenotypes in tup^isl-1 mutants. (A,B,D-J) Compared with wild-type Drosophila embryos, tup^isl-1 mutants are characterized by gaps in expression of all examined myocardial (Dmef2 and Tin) and all pericardial (Pc, Odd and Eve) cell markers. (C,K) Embryos that are transheterozygotic for tup^isl-1 and a deficiency that includes the tup locus, Df(2L)OD15, also show gaps in Dmef2 expression at stage 14 (arrows in C) and show a strong reduction of Tin-expressing cardiac cells at late stage 11 (asterisk in K). Arrowheads in K point to Tin-positive visceral mesodermal cells. as, amnioserosa; rg, ring glands.

tup is required for the formation of the dorsal vessel
All analyses were performed using embryos harboring the tup^isl-1allele. Molecular analysis of the tup^isl-1 allele suggests thatit has a mutation in the transcriptional regulatory region (Taoet al., 2007

). The extremely low expression level of Tup proteinor tup RNA in mutant embryos indicates that the tup^isl-1 alleleis a strong hypomorph (see Fig. S1A-F in the supplementary material).Consistent with its cardiac expression pattern, formation ofthe dorsal vessel is severely affected in tup^isl-1 embryos,as can be seen by the loss of Dmef2-expressing myocardial cells,as well as by the disrupted Pericardin (Pc) expression (Fig. 2A,B,D,E). Pericardinnormally demarcates pericardial cells and accumulates at thebasal membrane of the myocardial cells (Chartier et al., 2002

).The loss of pericardial cells in tup^isl-1 embryos is shown bygaps in Odd and Eve expression (Fig. 2F-I). The late cardiacphenotype at stage 15/16 has essentially been described before (Taoet al., 2007

). Our study aimed to determine the position oftup in the early cardiac transcriptional network, and whetherthe cause of the cardiac phenotype was distinct from secondaryeffects of problems in germ band retraction.

The loss of some Eve-expressing cell clusters is already seenby late stage 11 and indicates that the defects in heart developmentare not restricted to later stages when the two rows of myocardialcells come together at the dorsal midline. Reduced Tin and Dmef2expression was also observed in tup^isl-1/Df(2L)OD15 transheterozygotes (Fig. 2C,J,K).Since tup is expressed in the dorsal mesoderm around the timewhen cardiac progenitor cells become specified, it is likelythat tup plays a role in this process. Proper cardiac specificationrequires interactions between Tin, Pnr and Doc. Therefore, weexamined whether the expression of these factors is affectedin tup^isl-1 embryos. Indeed, tup mutants were characterizedby a strong reduction in Tin-, Pnr- and Doc2-expressing cellsat stage 11 (Fig. 3A-D,I,J). Since Tin and Doc are already expressedin the cardiac mesoderm at stage 10, before the onset of mesodermalTup expression, these findings indicate that tup is requiredfor their maintenance rather than their induction. The onsetof cardiac expression of Pnr and Tup seems to coincide at stage11 (Klinedinst and Bodmer, 2003; Reim and Frasch, 2005). Moreover,like Tup, Pnr is also expressed in the ectodermal layer anddouble staining for pnr RNA and Dmef2 or Wg protein demonstratedthat pnr expression is reduced in the mesoderm and ectodermin tup mutants (Fig. 3E-H). This suggests that Tup functionis also required in the ectoderm to maintain Pnr expression.

To further evaluate the functional relationship between tup,tin, pnr and Doc, we analyzed the expression of Tup in tin³⁴⁶,pnr^VX6 and Df(3L)DocA embryos. Staining for Tup protein in tin³⁴⁶embryos showed that the early Tup clusters are present, suggestingthat they are initially independent of tin (Fig. 4A,B). However,Tup expression was not maintained (Fig. 4C,D). Df(3L)DocA andpnr^VX6 mutants also showed a strong reduction in, or lack of,Tup-expressing cells (Fig. 4E,F). Together with the data above,these results point to an interdependency of all four factors: tup,tin, pnr and Doc.

Since Wg and Dpp are crucial growth factors in heart development,we also analyzed Tup expression in wg^CX4 and dpp^d6 embryos.Both mutants were characterized by a strong reduction in, orloss of, Tup expression (Fig. 4G,H). Similarly, as observedin tin³⁴⁶ mutants, Tup was initially present in the early cellclusters in wg^CX4 embryos at stage 11 (data not shown). Earlysteps in visceral mesoderm formation seemed to be unaffected intup^isl-1 mutants, whereas tup might play a role in the specificationof the Kr-expressing dorsal somatic muscle cells (see Fig. S2A-Din the supplementary material). In summary, these data demonstratethat tup is required for the proper specification of cardiacprogenitor cells and for the formation of the dorsal vessel.

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Fig. 3. tup is required for the normal expression of early cardiac transcription factors. (A,B) Drosophila stage 11 tup^isl-1 mutants are characterized by a reduction in Tin-expressing cells (arrows). (C,D) The Pnr expression domain is strongly reduced in tup^isl-1 mutants (arrows). (E,F) Double fluorescence labeling for Dmef2 protein and pnr RNA shows the mesodermal reduction of pnr expression in tup^isl-1 mutants (arrows). (G,H) Reduced pnr expression (arrows) in the ectoderm is demonstrated by co-staining for Wg protein. (I,J) Stage 11 tup^isl-1 mutants lack cardiac Doc2-positive cells (arrows). Arrowheads indicate missing Eve-expressing cells.

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Fig. 4. Tup expression requires the presence of early cardiac transcription factors and depends on wg and dpp signaling. (A-D) Tup expression is initiated in the cell clusters in Drosophila tin³⁴⁶ mutants (arrowheads in B) but is not maintained at later stages (compare C with D). (E) Myocardial Tup and Dmef2 expression is absent in Df(3L)DocA mutants. Since Doc mutants have been shown to also lack pericardial cells, the remaining Tup-expressing cells (green) are unlikely to be cardiac-related cells. (F) pnr^VX6 mutants also show a dramatic reduction in myocardial Tup- and Dmef2-expressing cells. (G,H) Tup expression at stage 13/14 depends on Wg (G) and Dpp (H) signaling. Arrowheads in all images point to Dmef2/Tup co-expressing cells, which appear yellow in the merged optical sections. Asterisks are placed in the region of the myocardial cell row, which has defects to various degrees in all mutants shown.

tup cooperates with tin, pnr and Doc during cardiogenesis
Next we tested whether tup interacts genetically with tin, pnrand Doc. For this purpose, we analyzed embryos that are transheterozygousfor tup^isl-1 and Df(3L)DocA, tup^isl-1 and tin³⁴⁶, or tup^isl-1and pnr^VX6. The phenotypes of these embryos were compared withthe phenotypes of single heterozygotes for each of the investigatedalleles. Each double transheterozygous combination resultedin obvious gaps within the Dmef2-expressing myocardial cellrows in $~$ 30% of the embryos analyzed (Fig. 5A-D and Tables 1 and2). Also, tup and tin cooperated to maintain normal Pnr expression,as tup^isl-1/+;tin³⁴⁶/+ transheterozygotes showed reduced stainingfor Pnr (72%, n=102) (Fig. 5E,F). Tin expression was reducedin tup^isl-1/+;Df(3L)DocA/+ (51%, n=98) and tup^isl-1/+;pnr^VX6/+(45%, n=111) embryos, demonstrating that the combined actionof these factors is required for proper cardiac specification (Fig. 5G-I).Only $~$ 8-13% of the single heterozygous embryos ( $~$ 100 embryos foreach combination were counted) had phenotypes comparable tothe double transheterozygotes. Taken together, these resultsfurther indicate that tup is required in combination with tin,pnr and Doc to properly specify and maintain a cardiac fate.

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Table 1. The number of double transheterozygous embryos that have gaps in the myocardial cell rows is significantly higher than in embryos with only one mutant allele

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Table 2. There is significant difference between the number of Dmef2-positive cells in embryos with and without gaps in the myocardial cell rows

Tissue- and cell-specific requirement for tup during cardiogenesis
As shown above, Tup is expressed in the dorsal ectoderm as wellas in the cardiac mesoderm, and in tup mutants expression ofTup protein is almost absent in both germ layers. Therefore,we wanted to distinguish between the mesodermal and a possibleectodermal contribution of tup function in cardiogenesis. Weinterfered with endogenous Tup function by expressing a deletionconstruct of tup, which lacks the homeodomain but contains bothLIM domains and is likely to act as a dominant-negative (UAS-tup ${Delta}$ HD) (O'Keefeet al., 1998

). When expressing UAS-tup ${Delta}$ HD in the mesoderm, weobserved a reduction in Tin-expressing cells (Fig. 6A,B). Asimilar phenotype was induced after expressing UAS-tup ${Delta}$ HD inthe ectoderm (Fig. 6D). To further investigate the mesodermaland ectodermal contribution of Tup for cardiogenesis, we aimedto rescue the Tin phenotype by co-expressing the full-lengthtup cDNA. When both constructs were expressed in the ectoderm,we observed a partial rescue in $~$ 53% of the embryos (n=74) (Fig. 6E). However, $~$ 82% of the embryos (n=48) in which UAS-tup ${Delta}$ HD and UAS-tup wereco-expressed in the mesoderm, still exhibited a strong phenotype (Fig. 6C).Since the LIM domains are known to act as protein-interactiondomains (Schmeichel and Beckerle, 1994

; Kadrmas and Beckerle, 2004

),this result implicates that the Tup LIM domains interact with,and thereby inhibit, other mesodermal factors, the functionsof which appear to be required for normal cardiogenesis butcannot be rescued by simultaneous expression of tup. To testwhether the LIM domains are required for Tup function in cardiogenesis,we expressed a UAS-tup ${Delta}$ LIM deletion construct in the mesoderm.This construct is expected to still bind to the DNA, but LIMdomain-mediated interactions with other proteins are disrupted.Mesodermal expression of UAS-tup ${Delta}$ LIM also resulted in a reductionof Tin-expressing cells (Fig. 6F), demonstrating the requirementof the LIM domains to mediate proper interactions between Tupand other proteins in cardiogenesis.

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Fig. 5. Genetic interactions between tup, tin, pnr and Doc. The cardiac phenotypes in transheterozygotic Drosophila embryos demonstrate that tup interacts genetically with all three factors. The phenotypes were compared with those of the cardiac markers in single heterozygotes, and were evaluated statistically for Dmef2 (see Tables 1 and 2). (A-D) Dmef2 expression in the wild type (A) and in embryos transheterozygotic for tup^isl-1 and pnr^VX6 (B), tup^isl-1 and tin³⁴⁶ (C), tup^isl-1 and Df(3L)DocA (D). Dorsal views of embryos at stage 15/16 are shown. Arrows point to gaps in the myocardial rows of the dorsal vessel. (E,F) Pnr is reduced in tup/tin transheterozygotic embryos (arrows in F). A lateral view of a stage 11 embryo is shown. (G-I) Tin expression in the wild type (G), and in embryos transheterozygotic for tup and pnr (H), and tup and DocA (I). Reduced Tin expression is seen in both cases (arrows in H,I). Dorsal views of stage 14 embryos are shown.

The reduction of mesodermal Tin-expressing cells after inhibitingTup in the ectoderm can only be explained if the function ofa secreted cardiogenic factor is impaired. Owing to their highlysimilar expression patterns, Dpp is a likely candidate. Althoughdpp expression was reduced in embryos expressing UAS-tup ${Delta}$ HD inthe ectoderm (Fig. 6G,H), we observed a stronger phenotype intup^isl-1 mutants (Fig. 6I). Hence, ectodermal Tup can regulatedpp expression, either directly or indirectly through Pnr. Incontrast to the relatively strong downregulation of early Tin expression,there was still a considerable number of Dmef2-expressing myocardialcells, with only some segments that had fewer than the normalsix Dmef2-positive cells (Fig. 6J,K,K'). Therefore, we analyzedTin expression throughout embryogenesis and observed that theinitial, strong reduction of Tin in embryos expressing UAS-tup ${Delta}$ HDin the mesoderm appears to recover over time, and by stage 16Tin expression was comparable to that of wild-type embryos (seeFig. S3B,E,H in the supplementary material).

This pattern of expression could either point to a temporalrequirement of tup for Tin expression, or be due to the twi-Gal4driver, the activity of which becomes weaker during embryogenesis.Because we have observed a similar phenomenon for Tin expressionin tup^isl-1 mutants (see Fig. S3C,F,I in the supplementary material),we favor the first possibility. Since Tup is expressed in pericardialcells throughout embryogenesis, we tested whether Tup functionis required at later stages to maintain this pericardial fate.We expressed UAS-tup ${Delta}$ HD in the pericardial cell lineage usingthe Dot-Gal4 driver (Kimbrell et al., 2002). Inhibition of Tupfunction in pericardial cells resulted predominantly in theloss of Odd-positive cells in one or more hemisegments in 63%of the embryos (n=122), as well as in lymph glands of reduced size(Fig. 6L,M). Conversely, overexpression of Tup in the pericardialcell lineage yielded additional Odd-expressing cells in severalhemisegments in 42% of the embryos (n=119) (Fig. 6N).

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Fig. 6. Germ layer- and cell-specific requirements of Tup at various stages of cardiogenesis. Drosophila embryos at stage 12 (A-F) or between stages 10 and 11 (G-I), shown from the lateral side with anterior to the left; or at stage 15/16 (J-M) or 14 (N) shown from the dorsal side. (A,B,D) Mesodermal and ectodermal inhibition of Tup function by expressing UAS-tup ${Delta}$ HD results in a reduction of Tin-positive cells (arrows in B,D). (C,E) Full-length tup (UAS-tup) can partially restore Tin when co-expressed in the ectoderm but not in the mesoderm. (F) Mesodermal expression of a Tup construct lacking the LIM domains (UAS-tup ${Delta}$ LIM) also affects Tin expression (arrows). (G-I) Tup is required for normal dpp expression as shown by in situ hybridization. dpp is reduced after ectodermal inhibition of Tup function (arrows in H). dpp is strongly reduced in tup^isl-1 mutants (I). (J-K') Mesodermal expression of UAS-tup ${Delta}$ HD results in a reduced number of Dmef2-positive myocardial cells. (K') An enlargement of the two segments (as delineated by the vertical lines) indicated by the brackets in K. (L-N) Inhibition of Tup function in the pericardial cell lineage results in loss of Odd-positive cells (arrow in M), including a subset of Odd-expressing lymph gland cells (arrowhead in M). Overexpression of Tup in this lineage induces additional Odd-positive pericardial cells (arrows in N). Odd expression in the lymph glands appears unaffected (arrowhead in N).

Our data show that Tup functions in the mesoderm, as well asin the ectoderm regulating dpp expression to guarantee normalheart development. The experimental approach of inhibiting andrescuing Tup function implicates that Tup interacts with differentproteins in the ectoderm and in the mesoderm to ensure normalcardiogenesis.

Mesodermal overexpression of Tup
The requirement of tup in cardiogenesis prompted us to investigate whetherTup might be sufficient to induce additional cardiac and/or pericardialcells. Early pan-mesodermal overexpression of Tup induced onlya slight increase in Tin-positive cells (Fig. 7A,B). Expressionof UAS-pnr^D4 results in a strong induction of ectopic Tin expression,as reported by Klinedinst and Bodmer (Klinedinst and Bodmer, 2003)(Fig. 7C). Co-expression of UAS-pnr^D4 and UAS-tup resulted ina similar phenotype to that seen upon mesodermal overexpressionof UAS-pnr^D4 alone (Fig. 7D). Double immunostaining for Tinand Tup in embryos overexpressing UAS-pnr^D4 revealed that theectopic Tin cells co-express Tup, but the clusters are heterogeneousbecause they also contain cells that only express Tup (Fig. 7C1-C3).Mesodermal overexpression of Tup induced an enlargement of theEve-positive cell clusters in 46% of the embryos (n=112) (Fig. 7E,F,I),whereas mesodermal overexpression of UAS-pnr^D4 resulted in the oppositephenotype in 62% of the embryos (n=151) at stage 11 (Fig. 7G,I).Co-expression of UAS-tup and UAS-pnr^D4 was able to rescue the effectinduced by overexpression of each factor singly (Fig. 7H,I),but to different extents. It is important to note here thatpnr^D4 is a very active allele and therefore cannot be fullycounteracted by tup. As a result, when both constructs are co-overexpressed,the phenotype of enlarged Eve-expressing clusters induced byUAS-tup was more efficiently `rescued' (from 46% to 6%) thanthe phenotype induced by UAS-pnr^D4 (from 62% to 46%). Mesodermaloverexpression of UAS-tup resulted in a moderate loss of Odd-positivepericardial cells and in the complete loss of Odd-positive cellsin the lymph glands (Fig. 7J,K). The same phenotype was observedwhen UAS-tin was expressed early throughout the mesoderm (Fig. 7L).When both factors were overexpressed, the effect on Odd-expressingpericardial cells did not appear to be synergistic (Fig. 7M).

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Fig. 7. Mesodermal overexpression of Tup reveals different functional relationships with other cardiac transcription factors. (A-D) Overexpression of Tup leads to a moderate expansion of Tin and some ectopic Tin-expressing cells on the lateral side of the embryo (arrows in B). Overexpression the Pnr allele pnr^D4 results in a strong ectopic induction of Tin across the whole lateral side of the embryo (arrows in C). Co-overexpression of Tup and Pnr^D4 mimics the phenotype of Pnr^D4 overexpression alone (arrows in D point to ectopic Tin-expressing cells). (C1-C3) The ectopic Tin-positive cell clusters induced by overexpression of Pnr^D4 alone are heterogenous. Some cells co-express Tin and Tup (arrow in C3), whereas others are only positive for Tup (arrowhead in C3). (E-I) Tup and Pnr counteract each other in Eve-positive pericardial cell specification. Overexpression of Tup results in additional Eve-positive cells within the clusters (arrows in F), whereas overexpression of Pnr^D4 leads to the complete loss of Eve-positive cell clusters (arrows in G). (H) Co-overexpression of Tup and Pnr^D4 can reduce the effects induced by each factor singly. (I) Pie charts showing the percentage of embryos with wild-type (WT, brown), expanded (+, yellow) or reduced (-, green) Eve-positive cell clusters. (J-M) Overexpression of Tup results in a moderate loss of Odd-positive pericardial cells (arrow in K) and to a strong reduction of Odd-positive lymph gland cells (arrowheads in J,K). Overexpression of Tin has a slightly stronger negative effect on the Odd-positive pericardial cells (arrows in L); however, the reduction of Odd-positive cells in the lymph glands appears to be less strong (arrow in L) than that caused by Tup overexpression (arrowhead in K). (M) Co-overexpression of Tup and Tin results in a similar phenotype to that seen for overexpression of Tin alone. Arrows point to the absence of Odd-positive pericardial cells; the arrowhead points to Odd-positive lymph gland cells.

In summary, an early pan-mesodermal overexpression of UAS-tupdoes not result in a dramatic overspecification of cardiac cells.Nonetheless, Tup can promote Tin expression, whereas it hasa negative effect on Odd-positive cells. These results provideinitial clues that Tup regulates heart and hematopoietic organdevelopment on a transcriptional level by acting as both anactivator and a repressor, depending on the context.

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Fig. 8. Tup as a new component of the Drosophila early cardiac transcriptional network. At stage 10, Tup is expressed in the ectoderm and is required for normal Pnr and dpp expression. Regulation of dpp expression through Tup may be direct or indirect (dashed line). Likewise, ectodermal Tup expression may be regulated by Dpp directly or indirectly through Pnr. After Wg and Dpp have induced a cardiac fate in the dorsal mesoderm by initiating and maintaining Doc and Tin expression, respectively, Pnr and Tup start to be expressed in the cardiac mesoderm by stage 11. All four factors are required to ensure proper cardiac specification of mesodermal cells. Black arrows indicate previously characterized interactions; red arrows indicate novel interactions with Tup as proposed in this study.

	DISCUSSION

TOP SUMMARY INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

The specification of a subset of mesodermal cells towards acardiac fate requires well-orchestrated interactions of a plethoraof factors. Drosophila is the model system of choice to decipherthe complex transcriptional network that initiates and sustainsa cardiac lineage. Our data place the LIM-homeodomain transcriptionfactor tup as an essential component in the early transcriptionalnetwork that specifies cardiac mesoderm.

After the initially broad expression domain of Tin has becomerestricted to the dorsal mesodermal margin, we first see Tupexpression in the cardiac mesoderm in $~$ 10 small clusters, whichco-express Eve. Slightly later, Tup is present throughout theTin-positive cardiac mesoderm and gene expression analyses intup^isl-1, tin³⁴⁶, pnr^VX6 and Df(3L)DocA embryos demonstratethat all four factors are required to maintain each other'sexpression (Fig. 8). Additionally, analyses of cardiac geneexpression in embryos that are transheterozygotic for tup andtin, pnr or Doc, showed that these factors interact geneticallyto specify heart cells.

Although it might be expected that Tup expression is lost intin mutants as these embryos are devoid of heart cells, it isinteresting that Tup expression in the early cell clusters isstill initiated. This finding is somewhat reminiscent of theobservation that the initiation of Doc expression is also independentof tin (Reim and Frasch, 2005). According to the temporal appearanceof Tup in the cardiac mesoderm with respect to Tin and Doc,tup is required for their maintenance rather than their initiation.By contrast, the onset of mesodermal Pnr and Tup expressionappears to coincide (Klinedinst and Bodmer, 2003; Reim and Frasch,2005). We did not resolve whether Tup is induced by Pnr or directlyby Dpp. A direct regulation by Dpp was implicated by the reducedexpression of Tup after mesodermal overexpression of UAS-brinker(data not shown), which is known to bind to dpp-response elementsof dpp target genes (Kirkpatrick et al., 2001). Conversely,we show that dpp expression depends on tup and our present datasuggest that this regulation requires pnr.

Germ layer-specific inhibition of Tup using a construct thatlacks the homeodomain, but contains the two LIM domains, revealedthat Tup can regulate cardiogenesis in the mesoderm as wellas from the ectoderm. Since the 69B-Gal4 driver has been reportednot to be strictly ectodermal (Klinedinst and Bodmer, 2003), itis possible that we also interfered with mesodermal Tup function.However, the mesodermal expression of 69B-Gal4 seems to be negligible (Baylieset al., 1995). The effect of ectodermal Tup inhibition on cardiogenesisin the mesoderm can only be explained if the function of a secretedgrowth factor is impaired. We have analyzed dpp expression andobserved a slight downregulation of its transcripts in embryosexpressing UAS-tup ${Delta}$ HD in the ectoderm. Since this effect mightnot be sufficient to account for the strong Tin phenotype, furtherexperiments will be required to determine whether additionalgrowth factors are affected.

To better determine the germ layer-specific contribution ofTup in cardiogenesis, we attempted to rescue the Tin phenotypeby co-expressing the full-length tup cDNA. Somewhat unexpectedly,we obtained a better rescue when both constructs were expressedin the ectoderm rather than in the mesoderm. Since the LIM domainspresent in tup ${Delta}$ HD can sequester LIM-domain-binding proteins (O'Keefeet al., 1998), a simple explanation for this finding is thatTup interacts with proteins that are present in the mesodermbut not in the ectoderm. Based on the data published by O'Keefeet al. (O'Keefe et al., 1998), it is reasonable to hypothesizethat in the mesoderm the LIM domains of tup ${Delta}$ HD not only act asa dominant-negative for Tup, but additionally for another, perhapsas yet unidentified, LIM-domain containing protein. Since ithas been shown that Pnr can bind Tup through the LIM domains (Biryukovaand Heitzler, 2005), we are likely to have interfered with Pnrfunction by overexpressing UAS-tup ${Delta}$ HD. The requirement of theLIM domains for proper cardiac specification is shown by thereduction of Tin-expressing cells after mesodermal expressionof the UAS-tup ${Delta}$ LIM construct. Further experiments are under wayto better resolve the molecular function of Tup in the differenttissues.

Since the mesodermal expression of UAS-tup ${Delta}$ HD resulted in a strongreduction of Tin-expressing cells at early stages of cardiacmesoderm formation, it was surprising to observe a rather low reductionof Dmef2-positive myocardial cells at later stages (15/16).To exclude the possibility that the twi-Gal4 driver does not sufficientlyexpress UAS-tup ${Delta}$ HD throughout embryogenesis, we repeated thisexperiment using the combined mesodermal driver twi-Gal4; 24B-Gal4.However, the phenotypes were not enhanced (data not shown).A time course for Tin expression in these crosses revealed thatTin appears to recover over time. A similar phenomenon can be seenin tup^isl-1 mutants, although it might not be as obvious becausethe mutants also lack ectodermal tup expression. In any case,the data is suggestive of a different temporal requirement for tupwith respect to tin expression. It is known that tin expressiondepends on different transcriptional activation events (Yinet al., 1997). Consistent with the onset of Tup expression inthe cardiac mesoderm at mid-stage 11, the earlier phases ofTin expression are unlikely to depend on Tup. Hence, the initialTin expression at stages 8-10 is sufficient to generate a considerable numberof Dmef2-positive myocardial cells at later stages (Zaffranet al., 2006).

Our analyses further implicate that Tup might act as a transcriptional activatoror repressor depending on the cellular context and on the factors withwhich it is co-expressed. This is most strikingly observed withrespect to the Odd-expressing pericardial and lymph gland cells.In tup mutants, Odd-positive cells are missing in both organs (Taoet al., 2007) (this study). A similar phenotype is seen whenTup is overexpressed in the mesoderm using the twi-Gal4 driver.The loss of Odd-expressing cells in lymph glands is reminiscentof the phenotype observed in tup mutants, although it is lesssevere. This differential occurrence of the phenotype indicatesthat tup can differentially regulate factors involved in cardiogenesisversus lymph gland development. This is substantiated by the findingof Tao et al. (Tao et al., 2007), who showed that mesodermaloverexpression of tup results in an increase in Hand expressionin the lymph glands, while Hand expression throughout the dorsalvessel is only mildly affected. Despite the loss of Odd-positivecells after early mesodermal tup overexpression, Tup is requiredin the pericardial and lymph gland cells at later stages to maintainOdd expression. Moreover, overexpressing tup in the pericardialcell lineage yields additional Odd-expressing pericardial cells andrescues Odd expression in the lymph glands.

To obtain more insight into possible functional interactionswith other cardiac transcription factors, we overexpressed tupin combination with pnr^D4. The latter is a highly active variantof wild-type pnr that contains an amino acid substitution inthe N-terminal zinc finger, which abolishes binding of Ush toPnr (Haenlin et al., 1997). Mesodermal overexpression of pnr^D4results in robust ectopic activation of Tin (Klinedinst and Bodmer,2003) and embryos co-overexpressing tup and pnr^D4 exhibit thesame phenotype. Most likely, a possible influence of Tup onPnr activity, regardless of whether it is positive or negative,is concealed by the strong gain-of-function pnr allele. However,analysis of Eve expression does provide insight into possible regulatoryinteractions between Tup and Pnr. Mesodermal overexpressionof each factor alone yields opposing phenotypes, and when bothfactors are co-overexpressed Pnr^D4 can efficiently counteractTup activity and prevent the overspecification of Eve cells.Vice versa, Tup can, although only moderately, counteract theeffect of Pnr^D4. It has been shown that during patterning ofthe thorax, Tup can antagonize the proneural activity of Pnrby forming a heterodimer, and that the physical interactionbetween Pnr and Tup is mediated by the two zinc fingers of Pnr (Biryukovaand Heitzler, 2005). Hence, the somewhat weak, but possiblyantagonistic, function of Tup towards Pnr^D4 in Eve-positivecell specification could be due to the amino acid substitutionencoded in the pnr^D4 allele, which might weaken the interactionbetween the two factors, as compared with wild-type Pnr. Overexpressionof a Tup construct that lacks both LIM domains did not resultin expanded Eve-positive clusters (data not shown), which strongly suggeststhat the effect of Pnr on Tup activity, as seen when both factorsare co-expressed, requires the presence of the LIM domains.

In summary, our data demonstrate the crucial role of tup inthe proper specification of cardiac mesoderm in an invertebrateorganism. Therefore, tup/Isl1 should be added to the core setof ancestral cardiac transcription factors. Consequently, thisimplicates that the evolution of the vertebrate four-chamberedheart does not necessarily require the acquisition of a novelnetwork of cardiac transcription factors. At least, it is unlikelythat tup/Isl1 is part of a regulatory network separate fromthat of tin/Nkx2.5, pnr/Gata4 and Doc/Tbx5/6 because it is an essentialfactor for the formation of the simple linear heart tube inthe fly.

Supplementary material
Supplementary material for this article is available at http://dev.biologists.org/cgi/content/full/136/2/317/DC1

Footnotes

We are grateful to M. Frasch, J. Skeath, G. Morata, B. Paterson,J. B. Thomas, S. Thor, I. Biryukova, P. Heitzler, the BloomingtonStock Center and the Developmental Studies Hybridoma Bank forproviding fly stocks and antibodies. We also thank S. Liebau,H. Kestler and I. O. Sirbu for confocal microscopy, statisticsand comments, respectively? This research was financed by agrant of the SFB 497, A8, to P.P. R.B. is supported by grantsfrom NHLBI at NIH. Deposited in PMC for release after 12 months.

REFERENCES

TOP
SUMMARY
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

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