collier transcription in a single Drosophila muscle lineage: the combinatorial control of muscle identity

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First published online 14 November 2007
doi: 10.1242/dev.008409

Development 134, 4347-4355 (2007)
Published by The Company of Biologists 2007

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collier transcription in a single Drosophila muscle lineage: the combinatorial control of muscle identity

Laurence Dubois, Jonathan Enriquez, Virginie Daburon, Fabien Crozet, Gaelle Lebreton, Michèle Crozatier and Alain Vincent^*

Centre de Biologie du Développement, UMR 5547 CNRS/UPS, IFR 109, Institut d'Exploration Fonctionnelle des Génomes, 118 route de Narbonne, 31062 Toulouse cedex 9, France.

^* Author for correspondence (e-mail: vincent{at}cict.fr)

Accepted 14 September 2007

SUMMARY

TOP
SUMMARY
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Specification of muscle identity in Drosophila is a multistep process:early positional information defines competence groups termed promuscularclusters, from which muscle progenitors are selected, followedby asymmetric division of progenitors into muscle founder cells(FCs). Each FC seeds the formation of an individual muscle withmorphological and functional properties that have been proposedto reflect the combination of transcription factors expressedby its founder. However, it is still unclear how early patterningand muscle-specific differentiation are linked. We addressedthis question, using Collier (Col; also known as Knot) expressionas both a determinant and read-out of DA3 muscle identity. Characterizationof the col upstream region driving DA3 muscle specific expressionrevealed the existence of three separate phases of cis-regulation,correlating with conserved binding sites for different mesodermaltranscription factors. Examination of col transcription in coland nautilus (nau) loss-of-function and gain-of-function conditionsshowed that both factors are required for col activation inthe `naïve' myoblasts that fuse with the DA3 FC, therebyensuring that all DA3 myofibre nuclei express the same identityprogramme. Together, these results indicate that separate setsof cis-regulatory elements control the expression of identityfactors in muscle progenitors and myofibre nuclei and directlysupport the concept of combinatorial control of muscle identity.

Key words: Cis-regulatory modules, collier (knot), nautilus (MyoD), Drosophila, Muscle identity

INTRODUCTION

TOP
SUMMARY
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Drosophila Collier (Col; also known as Knot) belongs to theCOE (Col/Olf1/EBF) family of transcription factors, which containsa single member in metazoans, except for vertebrates, in whichfour genes have been identified (Dubois and Vincent, 2001; Liberget al., 2002; Pang et al., 2004). col was initially characterisedfor its expression and function in a specific region of theembryonic head that corresponds to both a mitotic domain (MD2)and a gnathal parasegment (PS0) (Crozatier et al., 1996). colis also expressed in, and required for the formation of, a single somaticmuscle, the embryonic Dorsal/Acute 3 (DA3) muscle (Crozatierand Vincent, 1999), thereby providing a unique entry site forstudying the transcriptional control of muscle identity.

The embryonic musculature of Drosophila melanogaster is highly stereotyped,with a standard arrangement of around 30 somatic muscles ineach trunk hemisegment. Each muscle fibre is an individual syncitiumthat can be distinguished by its position, shape, epidermalattachment sites and innervation (Bate, 1993; Baylies et al.,1998). Muscle fibres are seeded by founder cells (FCs), whichare themselves generated from progenitor cells singled out frompromuscular clusters by Notch-mediated lateral inhibition (Carmenaet al., 1995; Ruiz Gomez and Bate, 1997). FCs undergo multiplerounds of fusion with fusion competent myoblasts (FCMs) to forma myofibre. The current view is that `muscle identity' transcriptionfactors (TFs) endow FCs with the capacity to execute the fusionand differentiation programme specific to each muscle fibre (Bayliesand Michelson, 2001; Frasch and Leptin, 2000). The `identityTF code', at least in part, reflects the initial position ofthe promuscular cluster and derived progenitor cell. Pioneeringwork on the control of expression of the homeodomain transcriptionfactor Even-Skipped (Eve) in dorsal muscle progenitors showedthat it involved the combinatorial activity of TFs functioningdownstream of Wingless (Wg), Decapentaplegic (Dpp) and receptortyrosine kinase (RTK) signalling, [dTCF (Pan - FlyBase), Mothers againstDpp (Mad) and Pointed (Pnt), respectively]. Integration of this positionalinformation and tissue-specific (mesodermal) information atthe level of the eve promoter was responsible for activating Eve-expressionin promuscular clusters (equivalence groups) from which Eve progenitorswere selected by Notch (N) signalling (Carmena et al., 2002; Carmenaet al., 1998; Halfon et al., 2000; Halfon et al., 2002). Large-scaleanalyses of gene expression in conditions of perturbation of componentsof Eve regulation suggested that related transcriptional codes couldbe responsible for different patterns of progenitor gene expression (Estradaet al., 2006; Philippakis et al., 2006; Sandmann et al., 2006).The eve enhancer reproducing Eve expression in muscle progenitorswas not active, however, in recruited FCM nuclei (Halfon etal., 2000), indicating that different cis-regulatory elements(and TFs) could be required for specifying promuscular clustersand maintaining a TF identity code.

Here we used Col expression as both a determinant and read-outof DA3 muscle identity to ask how positional information thatdefines promuscular clusters is relayed into the FC identityand extended to fused FCM nuclei. We first identified the cis-regulatoryregions controlling col transcription at several steps duringformation of the DA3 muscle and defined a DA3-muscle-specificcis-regulatory module (CRM). Detailed analysis of this CRM revealedthe existence of three separate steps: Col activation in promuscularclusters, upregulation in the selected progenitor and DA3 FCand activation in the nuclei of FCM incorporated in the growingDA3 myofibre during the muscle fusion process. Comparison ofthe DA3 muscle CRM between several Drosophila species identifieda set of conserved sequence motifs with functional significancesupported by the expression patterns of reporter genes containingthe D. virilis (D. vir) DNA. Conserved binding sites for themesodermal TFs Twist (Twi), Nautilus (Nau, the Drosophila orthologueof MyoD) and Mef2 (Andres et al., 1995; Huang et al., 1996; Ipet al., 1992; Kophengnavong et al., 2000) and a putative Col-bindingsite necessary for positive autoregulation were present in differentsubdomains of the DA3 muscle CRM, correlating with the separatephases of col regulation. We show that col auto-regulation iscrucial for a reiterative, two-step activation of col transcriptionin each `naïve' FCM incorporated into the DA3 muscle. Nau,which was previously reported to be required for DA3 muscle formation(Keller et al., 1998), is also required for col transcriptionin the DA3 muscle, beyond the FC stage. Pan-FC expression ofeither Col, Nau or both proteins resulted in ectopic col transcriptionin different sets of muscles. Together, our results show thatseparate sets of cis-regulatory elements ensure col activationin the DA3/D05 promuscular cluster, progenitor and DA3 myofibre.Nau and Col act together in ensuring that all nuclei withinthe DA3 myofibre activate Col and express the same differentiationprogramme, thereby directly supporting the concept of combinatorialcontrol of muscle identity.

MATERIALS AND METHODS

TOP
SUMMARY
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Drosophila strains
The following strains were used: w¹¹¹⁸ as a wild-type (wt) referenceand for P element transformation using standard procedures (Rubinand Spradling, 1982); rp298-Gal4 (Menon and Chia, 2001); col¹ (Crozatieret al., 1999) and nau¹⁸⁸ (Balagopalan et al., 2001) EMS-inducedloss-of-function alleles; vg^83b27-R, a ${gamma}$ -ray induced amorphicallele; UAS-col (Vervoort et al., 1999); hs-col (Crozatier andVincent, 1999); UAS-nau (Keller et al., 1997); UAS-lacZ (BloomingtonStock Center, Indiana, USA). UAS-mcd8::GFP (Grueber et al., 2003).

Plasmid constructions and transgenic lines
The P5cl construct was described in Crozatier and Vincent (Crozatierand Vincent, 1999). Other Pcl constructs were generated by cloningdifferent fragments of col upstream DNA (for the restrictionsites used, see Fig. S2 in the supplementary material) intopCaSpeRβ-gal or pPTGal4 (Sharma et al., 2002). Mutagenesisof the putative Nau- and Col-binding sites in P2.6cl was doneby PCR. The D. vir constructs were generated by restriction digestionof genomic DNA isolated from a ${lambda}$ phage library (J. Tamkun, Universityof California, Santa Cruz, CA).

Immunohistochemical staining and in situ hybridisation
Embryos were fixed and processed for antibody staining and/orin situ hybridisation as described (Crozatier et al., 1996).The nau intronic probe covers all three nau introns and thetwo corresponding exons. The following primary antibodies wereused: rabbit anti-Col (1/400); mouse anti-Col (1/100); rabbit anti-MHC(1/500; D. Kiehart, Duke University, Durham, NC); mouse anti-β-gal(1/1000, Promega); rabbit anti-GFP (1/1000 Torrey Pines Biolabs);Secondary antibodies were Alexa Fluor 488 and Alexa Fluor 647 conjugatedgoat anti-rabbit, Alexa Fluor 647 conjugated goat anti-mouse (MolecularProbes 1/300); Rhodamin RedX conjugated donkey anti-mouse (Jackson Laboratory1/300); biotinylated goat anti-mouse (Vector Laboratory, 1/1000). Fordouble fluorescent in situ hybridisation/immunostaining, weused biotinylated col and digoxygenin-labelled nau intronic probesand the ABC kit from Vector Laboratory, followed by fluorescent tyramidestaining (Alexa fluor 555 or 488 conjugated tyramide from Molecular Probes)and Fast Red. Primary antibodies against Col, GFP or MHC wereused at five times the usual concentration. Monoclonal Col antibodieswere generated in collaboration with Jeannine Boyes and GeorgesDelsol, U 563 INSERM, Toulouse Purpan.

Sequence alignments and transcription factor binding sites
Pairwise sequence alignments of col upstream sequences from variousDrosophila species (http://flybase.bio.indiana.edu/static_pages/news/articles/2007_03/genomes_papers3.html) weredone using NCBI-BLAST (bl2seq), Genome Browser (UC Santa Cruz)and Evoprinter (NINDS, NIH, Bethesda) and manually edited following eye-inspection.Search for individual binding sites for transcription factors madeuse of Genomatix Matinspector, Possum (http://zlab.bu.edu/~mfrith/possum/), cis-analyst (http://rana.lbl.gov/cis-analyst/cgi/viewer.php) andFlyEnhancer (http://genomeenhancer.org/fly; M. Markstein) andmanual inspection based on the literature. Access to the Mef2and Twi in vivo binding sites (Sandmann et al., 2007; Sandmannet al., 2006) was via the E. Furlong's lab site (http://furlonglab.embl.de/data/).

RESULTS

TOP
SUMMARY
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Modular organisation of the col cis-regulatory region
col belongs to the class of Drosophila regulatory genes withnumerous introns, large amounts of flanking sequence and multiple expressionsites (Crozatier and Vincent, 1999; Nelson et al., 2004; Philippakiset al., 2006). During embryogenesis, col is expressed in the MD2/PS0head region, the somatic DA3 muscle, precursor cells of thelymph gland, a small set of multidendritic (md) neurons of theperipheral nervous system and specific neurons of the centralnervous system (CNS) (Baumgardt et al., 2007; Crozatier et al.,2004; Crozatier et al., 1999; Crozatier and Vincent, 1999; Orgogozoand Schweisguth, 2004). We previously generated a lacZ reportertransgene (P{5col::lacZ}, abbreviated P5cl, Fig. 1A) containing5 kb of col upstream DNA, which faithfully reproduced col transcriptionboth in the MD2/PS0 and the DA3 muscle, starting at the progenitorstage and not in promuscular cluster(s) (Crozatier and Vincent,1999). To identify the missing cis-regulatory information, wetested a longer construct containing the entire 9 kb regionseparating col from CG10200, the next predicted upstream gene (http://flybase.bio.indiana.edu/; P9cl,Fig. 1A). In addition to the head and DA3 muscle, P9cl expressionreproduced col expression in md neurons and a subset of neuronsin the CNS. A DNA fragment located further upstream, betweenCG10200 and the next predicted gene CG10202, was independentlyshown to drive col expression in the anteroposterior organiserof the wing imaginal disc (Hersh and Carroll, 2005). However,neither this construct nor P9cl reproduced Col expression in promuscularclusters (Fig. 1D). The col transcription unit is immediatelyflanked at its 3' end by another gene, BEAF32 (Fig. 1A), makingrather unlikely the presence of cis-regulatory elements withinthis region. However, it contains ten different introns, of totallength around 30 kb, the cis-regulatory content of which remainsto be assessed (see Discussion).

To delineate more precisely the CRM driving col expression inthe DA3 muscle, we tested a series of constructs containing2.6, 2.3, 1.6 and 0.9 kb of DNA upstream of the col transcriptionstart site, respectively (Fig. 1A). P2.6cl retained the informationnecessary for col expression in MD2/PS0 and the DA3 progenitorand muscle (Fig. 1C), although we noted that P2.6cl expressionin muscle progenitors was less robust than P9cl. P2.3cl wasalso activated in MD2/PS0 at stage 6 and the DA3 muscle. However,unlike P9cl or P2.6cl, P2.3cl was not activated in the DA3/DO5progenitor but only at the FC stage (Fig. 1C; ectopic lacZ expressionwas observed in clusters of neuroectodermal cells at embryonicstage 11). This difference indicated that cis-regulatory elementsrequired for col expression in the DA3/DO5 progenitor reside betweenpositions -2.6 and -2.3 and act separately from those requiredfor expression in the DA3 FC and muscle. P1.6cl was only activein MD2/PS0, whereas no expression at all could be detected withP0.9cl (data not shown). Together, expression data from thisseries of reporter constructs allowed the mapping of the CRMrequired for col-specific expression in the DA3/DO5 muscle progenitorand DA3 FC/myofibre to a DNA fragment between positions -2.6and -1.6 upstream of the col transcription start (Fig. 1E).

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Fig. 1. Mapping of the col DA3 muscle CRM in Drosophila. (A). Schematic representation of the col genomic region. Coding exons and the 5' and 3' untranslated regions are indicated by black and white boxes, respectively. The positions of the immediately upstream and downstream predicted genes (http://flybase.bio.indiana.edu/), CG10200 and BEAF-32, are indicated by grey boxes and their direction of transcription by arrows. The extent of col upstream region present in each lacZ reporter gene, P9cl to P0.9cl is indicated by a black line. (B) Diagrammatic, colour-coded representation of the different col expression sites in stage 11 and 14 embryos. (C) In situ hybridisation showing expression of P2.6cl, P2.3cl and P1.6cl, compared to endogenous col, at embryonic stages 6, 11, 12 and 14. (D) Close-up view of the DA3 promuscular cluster and progenitor in the T2 and T3 segments of a P9cl embryo at stage 11, stained for Col (green) and β-gal (red). Unlike Col, lacZ expression is restricted to the progenitor cell. (E) Schematic representation of the modular organisation of the col cis-regulatory region, underlining the position of the DA3 muscle CRM.

Conserved motifs and TF-binding sites in the col upstream region
We took advantage of the recently available genome sequencesof several Drosophila species to search for conserved motifsin the col upstream DNA, as it has often proven to be effectiveto identify functionally important cis-regulatory elements (Wassermanet al., 2000

; Yuh et al., 2002

). Among these species, D. virilis(D. vir) is the most distant from D. melanogaster (D. mel) (Tamuraet al., 2004

). We first verified that Col expression in D. virwas similar to that in D. mel embryos (Fig. 2A and see Fig.S1 in the supplementary material) and could infer from thisthat the regulatory information controlling col transcriptionin the DA3 muscle lineage has been conserved. Sequence comparisonof 9 kb of the col upstream region between D. mel, D. vir andfour other Drosophila species, D. yakuba, D. ananassae, D. pseudoobscuraand D. mojavensis revealed numerous stretches of high sequenceconservation, of sizes up to 100 bp (see Fig. S1 in the supplementary material).Ten conserved motifs of size >20 bp, numbered 1 to 10 from5' to 3', were found in the same order and at the same relativeposition between position -2.6 and the start of transcriptionin all six Drosophila species (Fig. 2B and see Fig. S2 in thesupplementary material). To test the relevance of this conservation,we generated lacZ reporter constructs containing either D. viror D. mel DNA (Fig. 2B). P.3.4cl^vir corresponds to D. mel P2.6cl,whereas P3.4-1.3cl^vir and P2.6-0.9cl are truncated versionscovering motifs 1 to 10. All four reporter genes showed expressionin the DA3 muscle, starting at the progenitor stage, confirmingthe evolutionary conservation of a DA3-muscle-specific CRM (Fig. 2A).A Gal4 driver line containing only the -2.6 to -1.6 region (P2.6-1.6cG),harbouring only motifs 1 to 7 (Fig. 2B), was also specificallyexpressed in the DA3 muscle (Fig. 2A). This confirmed that theDA3 muscle CRM is located between positions -2.6 and - 1.6.We noticed, however, that expression of P2.6-1.6cG was weakerand more sporadic than P2.6-0.9cl, suggesting the existenceof cis-regulatory element(s) between positions -1.6 and -0.9contributing to robust DA3 muscle expression. We then searchedwithin the conserved motifs 1 to 10 for consensus binding sitesof known TFs that could account for col activation in the DA3muscle. This identified a binding site for the mesodermal basic helix-loop-helix(bHLH) protein Twi (Ip et al., 1992

; Kophengnavong et al., 2000

)(within motif 2 Fig. 2B), correlating well with the positionof the muscle progenitor cis-element (Fig. 1E) and a potentialEBF/Col-binding site (Travis et al., 1993

) within motif 7. Furthervisual inspection of the sequence alignments identified otherconserved TF-binding sites, including one Mef2-binding site(Andres et al., 1995

) within the -1.6 to -0.9 fragment and oneconsensus binding site for Nau (Huang et al., 1996

; Kophengnavonget al., 2000

). On the one hand, the position of the Mef2 sitecorrelated well with the requirement of the -1.6 to -0.9 fragmentfor robust DA3 muscle expression (Fig. 2A). On the other hand,the presence of a Nau-binding site was particularly intriguingas Nau is required for DA3 muscle formation (Keller et al.,1998

). Potential binding sites for other TFs (Bergman et al.,2005

; Vlieghe et al., 2006

) could be found in the DA3 CRM, butwe limited here our annotation to the conserved sites (see Fig.S2 in the supplementary material). The relative paucity of knownTF-binding sites in the conserved sequence motifs found in theDA3 muscle CRM leaves largely open the question of the rolesof these motifs in col regulation.

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Fig. 2. Conserved cis-regulatory elements and TF-binding sites in the DA3 muscle CRM. (A) Col expression in a stage 14 D. vir embryo (top left) and in situ hybridisation to lacZ transcripts showing expression of different D. vir and D. mel col reporter genes, as indicated in each panel. Note that P2.6-1.6cG is a Gal4/UAS-lacZ line. (B) Diagrammatic representation of the relative positions of conserved motifs, numbered from 1 to 10 and potential binding sites for Twi, Nau, Col and Mef2 in the DA3 muscle CRM (for details, see Fig. S2 in the supplementary material). (C,D) Ubiquitous hs-col driven Col expression specifically activates col-lacZ reporter genes in the VL1 muscle (white arrow), as shown here for P2.6cl (C). This is mediated by conserved cis-regulatory elements in the DA3 muscle CRM (D).

Ectopic activation of col transcription reveals a muscle TF code
Heat-shock-driven, ubiquitous expression of the Col proteinactivated endogenous col transcription in a few muscles otherthan DA3, mainly the VL1 and, more sporadically, the DA2 muscle (Crozatierand Vincent, 1999

). By using different col-lacZ reporter genes,we mapped the cis-regulatory element(s) responsible for thismuscle-specific activation to the DA3 muscle CRM (Fig. 2B-D anddata not shown). As it is restricted to the DA3 and VL1 (andpossibly DA2) muscles, we reasoned that col auto-activationwas dependent upon a specific combination of TF expressed inthese muscles. Of the known TFs expressed in somatic muscles,only Vestigial (Vg) and Nau are expressed in DA3 and VL1 (Bateet al., 1993

; Dohrmann et al., 1990

; Keller et al., 1998

; Patersonet al., 1991

). nau mutant embryos lack a subset of muscle fibres,with DA3 being the most severely affected (Balagopalan et al., 2001

;Keller et al., 1998

). By contrast, no muscle phenotype has yetbeen described for vg loss-of-function mutations. vg mutantsshow reduced wings and severe flight muscle defects but areviable and fertile, allowing the study of their maternal pluszygotic phenotype. We did not observe abnormal Col expressionor abnormal DA3 muscle formation in vg mutant embryos, indicatingthat Vg is not required for formation of this muscle (data not shown).

col activation in nuclei of fused myoblasts: a reiterative process endowing all nuclei of the DA3 myofibre with the same transcriptional programme
In situ hybridisation with a col intronic probe that labels nascenttranscripts revealed that col transcription is activated in thenuclei of those FCMs that are recruited to form the DA3 muscle (Crozatierand Vincent, 1999). To further investigate the mechanisms behindthis observation, we compared the patterns of Col accumulationand col transcription during the process of DA3 muscle formation(Fig. 3A-C). We found that, throughout the FC/FCM fusion phase(stage 12-15), each DA3 muscle syncitium contains on averageone or two nuclei, which stain positive for Col but do not transcribecol (see also Fig. 4). Close-up analysis of fusion events instage 13 embryos further revealed that only nuclei containing highlevels of Col protein activated col transcription (Fig. 3A).This strongly suggested that Col accumulation is a prerequisitefor auto-activation in newly fused FCM nuclei. In support ofthis interpretation, all the DA3 muscle nuclei transcribe colafter completion of the muscle fusion process (Fig. 3B), althoughthis uniform expression phase is only transient, as col transcription declinesabruptly during stage 16 to become undetectable (Fig. 3C). Fromthese observations, we conclude that activation of col transcriptionoccurs through a reiterative two-step mechanism, ensuring thesame transcriptional programme to all nuclei of the DA3 myofibre.In a first step, nuclei from FCMs newly incorporated into thegrowing syncitium import some of the Col protein present inthe muscle precursor (inset in Fig. 3A). In a second step, coltranscription is turned on in these nuclei.

Col and Nau are required for col transcription during DA3 muscle fusion
First evidence for col autoregulation during DA3 muscle formation camefrom the observation that col transcription is not maintainedin the DA3 FC in col mutant embryos (Crozatier and Vincent,1999). In order to investigate this phenotype in more detail,we constructed a P9col-Gal4 driver (P9cG), allowing us to expressa membrane-bound form of GFP in the DA3 muscle progenitor andto specifically follow the fate of this progenitor in col mutantembryos (UAS-mcd8GFP/P9cg; Fig. 3D). In wt embryos, mCD8GFPremains expressed and is detected both intracellularly and atthe plasma membrane of the DA3 myofibre. In col mutant embryos,mCD8GFP expression is lost early but stability of the proteinat the plasma membrane allows the detection of the mutant DA3 fibres.This experimental set-up confirmed that fusion of FCMs withthe DA3 FC is drastically impaired in col mutant embryos andthat col transcription is neither maintained in the DA3 FC noractivated in the nuclei of FCM, which sometimes fuse to forman abortive DA3 muscle precursor (Fig. 3E). These data establish thatcol auto-regulation and the muscle DA3 identity programme are intimatelyconnected.

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Fig. 3. col activation in FCM nuclei incorporated in the DA3 myofibre in Drosophila. (A-C) col transcription in wt DA3 muscle precursors, visualised by in situ hybridisation to col primary transcripts (red dots), immunostaining for Col (green) and nuclear staining (blue). (A'-C') Blue and red channels; (A''-C'') green channel. (A) Stage 14 embryo. The DA3 muscle precursor contains several nuclei; the two distalmost have already accumulated a high level of Col protein and activated col transcription. One central nucleus starts accumulating Col protein (lower inset) but does not yet transcribe col. Two other FCM have probably fused but not started to import Col protein (surrounded by a dashed line in A', upper inset). Another FCM has started engaging in the fusion process, (dashed notch in A'). (B) Stage 15 embryo. At this stage, each DA3 muscle nucleus contains high levels of Col protein and transcribes col. (C) Stage 16 embryo. All the DA3 muscle nuclei still contain high levels of Col protein but col transcription has almost completely ceased. (D,E) In situ hybridisation to col primary transcripts (red dots) in (D) wt and (E) col¹ mutant embryos (two segments are shown). A membrane-targeted form of GFP expressed under control of the col promoter (P9cg construct) allows the visualisation of the DA3 muscle (green). Note the complete absence of col transcription in col mutant embryos (E). The white arrowhead points to a dorsal md neuron expressing Col. Scale bar: 5 µm.

Nau activity is also required for formation of the DA3 muscle,although the described DA3 nau mutant phenotype is not as severeas for col (Keller et al., 1998

). The presence of a consensusNau-binding site in the col DA3 muscle CRM raised the possibilitythat one Nau function could be to regulate col transcription.To address this possibility, we first compared nau and col transcriptionin wt DA3 muscles, using in situ hybridisation to primary transcriptsand Col immunostaining. This revealed that col and nau are transcribedtogether in the DA3 progenitor, FC and muscle precursor up toearly stage 13 (Fig. 4A-C). Subsequently, only col transcriptionpersists in the DA3 muscle (Fig. 4D). We then looked at coltranscription in embryos homozygous for the null allele nau¹⁸⁸(Balagopalan et al., 2001

; Wei et al., 2007

). Based on Col andMyosin heavy chain (MHC) antibody staining (Fig. 4E,F and datanot shown) the DA3 muscle was completely absent in around 5%of segments, abnormal in orientation in 45% and rather normal-lookingin about 50% of segments, consistent with previous reports (Keller etal., 1998

). Low amounts of Col protein were observed in nuclei ofthe `normal-looking' DA3 muscles (Fig. 4E,F), allowing us tolook at col transcription in these nuclei. In wt embryos atstage 15, each DA3 muscle syncitium contains on average ninenuclei, which are all strongly stained with Col antibodies,and seven to eight are positive for col transcription (Fig. 4E;see also Fig. 3B). The DA3 fibres present in nau¹⁸⁸ embryoscontained only seven nuclei on average, with most showing alow level of Col protein. However, at most two or three of thosetranscribed col (Fig. 4F). This result indicated that Nau activityis required, in addition to Col, for activation of col transcriptionin the FCM nuclei that are recruited by the DA3 FC. The Colprotein that is detected in nau mutant embryos probably derivesfrom earlier, Nau-independent col transcription. Supporting thisconclusion, one nucleus, probably the FC nucleus, shows highlevels of col transcripts in nau mutant embryos at late stage12, when DA3 muscle precursors contain two or three nuclei (Fig. 4G,H).In summary, nau and col are expressed in the DA3 FC and bothNau and Col are required for col activation in the nuclei ofnewly recruited FCM, thereby ensuring that all nuclei withinthe DA3 myofibre acquire the same identity.

The combinatorial activity of Nau and Col controls col expression
To further test the hypothesis of a combinatorial role of Nauand Col in conferring the DA3 muscle its identity, we examinedthe activation pattern of P2.6cl at stage 15 after either Naualone, Col alone or Nau+Col were ectopically expressed in allmuscle FCs (rp298Gal4 driver) (Menon and Chia, 2001). rp298Gal4-drivenCol expression resulted in ectopic P2.6cl expression in severalmuscles other than DA3, including DA2, DT1 and VL2, althoughthis expression was most robust in VL1, as seen in hs-col experiments(Fig. 5A,B), without major phenotypic effects, at least at thelevel of muscle fibre morphology (data not shown). By contrast,rp298Gal4-driven Nau expression, while altering the patternof muscle fibres, as previously documented with a heat-shockconstruct (Keller et al., 1997), provoked ectopic expressionof P2.6cl only in a single muscle, the DA2 muscle (Fig. 5C).These data confirmed that, despite a more general role thanCol in somatic myogenesis (Keller et al., 1997; Wei et al., 2007),Nau is generally unable by itself to ectopically activate coltranscription. When Col and Nau were expressed together, P2.6clwas activated in the same muscles as with Col alone, but much morestrongly (compare Fig. 5B with D), confirming that Nau potentiatesthe ability of Col to activate its own transcription. Interestingly,P2.6cl was activated by Nau+Col in a few muscles, includingthe SBM muscles, which did not respond to the presence of Colalone, indicating that Nau and Col may act synergistically. Still,many muscles remained refractory to this combination and didnot express P2.6cl, suggesting that other competence factorsare lacking or that negative regulation exerted by Notch and/orother factors may be dominant in these muscles.

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Fig. 4. Nau-dependent col transcription during the DA3 muscle fusion process in Drosophila. (A-D) Double in situ hybridisation with intronic probes for col (green) and nau (red) nascent transcripts and Col immunostaining (blue) show that nau and col are co-expressed in (A) the DA3/DO5 progenitor cell, (B) the DA3 FC (outlined by a plain line) and (C), the DA3 muscle precursor when it contains two to three nuclei (outlined). nau remains transcribed in the DO5 FC (dashed outline in B), whereas col transcription is rapidly turned down. (E-H) col transcription (green dots) in (E,G) wt and (F,H) nau¹⁸⁸ mutant embryos (two segments are shown); the DA3 muscle is visualised by immunostaining for Col (red) and MHC (blue in E,F). In stage 15 nau¹⁸⁸ mutant embryos (F), the DA3 muscle is reduced, compared to wt (E) and most nuclei do not transcribe col. At stage 12, col expression in the DA3 muscle precursor (asterisk) when it contains two to three nuclei is similar in (H) nau¹⁸⁸ and (G) wt embryos, although only one nucleus, probably the FC nucleus, expresses high levels of col transcripts in nau¹⁸⁸ embryos. Arrowheads indicate col transcription in a dorsal multidendritic neuron. Scale bars: 5 µm.

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Fig. 5. Nau and Col separately and synergistically activate ectopic col transcription in specific subsets of muscles. (A) P2.6cl expression in the DA3 muscle in stage 15 wt embryos, visualised by β-gal antibody staining. (B) rp298Gal4-driven Col expression of in all FCs activates P2.6cl in a subset of somatic muscles cells, activation being most robust in the VL1 muscle. Nau expression (C) is unable to activate ectopic P2.6cl expression, except for, sporadically, the DA2 muscle. (D) Together, Col and Nau activate P2.6cl expression in a large number of somatic muscles in addition to VL1. A schematic representation of the abdominal muscle pattern is shown of the right side of each panel to indicate the P2.6cl expressing muscles. The DA3, DA2 and VL1 muscles are designated by an arrowhead, a dot and an arrow, respectively.

The control of col transcription by Nau+Col is probably direct
The evolutionary conservation of a Nau-binding site and a potential EBF-bindingsite within the DA3 muscle CRM (Fig. 2B and see Fig. S2 in the supplementary material)suggested that regulation of col transcription by Nau and Colcould be direct. We independently mutated the putative Nau-and EBF-binding sites within the P2.6cl construct, giving riseto P2.6cl^nau and P2.6cl^col, respectively (Fig. 6F). P2.6cl^nauexpression was either lost from the DA3 muscle or much reducedcompared with P2.6cl (Fig. 6A,C), suggesting that Nau directlyregulates col transcription. Unlike the case with P2.6cl, however,ectopic P2.6cl^nau expression was observed, indicating that themutated E-box in the Nau site could also mediate binding ofrepressing factor(s) in absence of Nau. Col binds in vitro tothe EBF consensus binding site (TTCT/CNNGGGAA) (Travis et al.,1993

), consistent with sequence conservation of the COE DNA-bindingdomain (Dubois and Vincent, 2001

) (V.D., unpublished). The closestmatch to the consensus EBF recognition site found within theDA3 CRM is the sequence ATGTCTGGGGAT, which is part of the conservedmotif 7 (Fig. 6F and see Fig. S2 in the supplementary material).Gel-shift assays and immunoprecipitation of DNA-protein complexesformed by co-incubation of Col with synthetic oligonucleotidesoverlapping this predicted EBF-binding site failed to revealstrong binding in vitro (V.D., unpublished). Nevertheless, DA3-specificexpression of P2.6cl^col in vivo was almost undetectable whenthis site was mutated (Fig. 6B,F), suggesting that it mediatescol auto-regulation. To provide a different test of this in vivofunction, we looked at P2.6cl^col activation in conditions ofectopic Col expression. Unlike P2.6cl (Fig. 6D), P2.6cl^col expressionwas activated very weakly, if at all, in the VL1 (and DA2) muscles(Fig. 6E). These results reinforce the conclusion that the predicted EBF/Col-bindingsite present within the conserved motif 7 is required for positivecol autoregulation.

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Fig. 6. col transcription in the DA3 muscle precursor depends upon a Nau and a potential Col-binding site in the DA3 muscle CRM. (A) Col and P2.6cl expression in wt Drosophila embryos at stage 15, visualised by Col (red) and β-gal (green in the right and white in the left panel) antibody staining. (B,C) P2.6cl expression is lost when either the putative EBF/Col- (B) or Nau- (C) binding site present in the DA3 muscle CRM is mutated. Red dots in A and C correspond to Col expression in md neurons. (D) Col expression in all FCs (rp298-Gal4/UAS-col) induces ectopic P2.6cl expression in the VL1 (arrow) and DA2 (dot) muscles, as visualised by β-gal immunostaining; the arrowhead points to the DA3 muscle. (E) Ectopic expression of P2.6cl is not observed when the EBF/Col-binding site is mutated. (F) The consensus EBF- and MyoD-(Nau) binding sites (Huang et al., 1996

; Travis et al., 1993

) are represented above the predicted sites found within the DA3 muscle CRM. The mutated positions introduced in P2.6cl^col and P2.6cl^nau are shown in red.

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Fig. 7. A model for the combinatorial coding of DA3 muscle identity in Drosophila. (A) Col is activated in one (T1-T3 segments) and two (A1-A2 segments) promuscular clusters (Crozatier and Vincent, 1999

), in response to positional and mesodermal cues. This first step is probably mediated by clusters of relevant TF-binding sites [light orange boxes (Philippakis et al., 2006

)], including Twi-binding sites (+) (Sandmann et al., 2007

) that are located within the col upstream region and introns. Col expression subsequently becomes restricted to the DA3/DO5 progenitor (orange cell) by lateral inhibition (Crozatier and Vincent, 1999

). We postulate that positive inputs from TFs binding to the -2.6 to -2.3 fragment, including Twi, are sufficient to allow P2.6cl activation in the selected DA3/DO5 progenitor, upon relief of N repression. (B) Following division of the progenitor, restriction of Col expression to the DA3 FC involves positive auto-regulation in this FC and negative regulation by N in the sibling DO5 FC. From this stage, a combination of Nau and Col activity is required for col transcriptional activation in the FCM nuclei, which are recruited by the DA3 FC to form a myofibre, thereby ensuring that all nuclei in the DA3 muscle express the same identity programme.

	DISCUSSION

TOP SUMMARY INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

The stereotyped pattern of Drosophila body wall muscles relies uponthe specification of FCs that seed the formation of individualmuscles at specific positions in the somatic mesoderm (Baylieset al., 1998

; Rushton et al., 1995

). The current view is thatthe properties specific to each muscle result from the selectiveexpression, in each FC, of distinct combinations of `muscle identity'TFs. However, experimental evidence for such a combinatorialcode has remained sparse. We addressed here this question, usingas a paradigm Col expression as both a determinant and read-outof DA3 muscle identity.

Three separate steps in the transcriptional control of muscle identity
Functional dissection of the DA3 muscle CRM present in the col upstreamregion showed that col expression in the DA3 FC can be separatedfrom its expression in the DA3/D05 progenitor and the promuscular cluster.It thus revealed the existence of three steps in the transcriptional controlof muscle identity (Fig. 7). That col expression in the DA3/D05progenitor could be uncoupled from that in promuscular clusterswas in apparent contradiction with the previous conclusion frompioneering studies on Eve expression in dorsal muscle progenitorsthat this expression issued from Eve activation in promuscularclusters. Restriction of Eve expression to progenitors was considereda secondary step, mediated by N-signalling during progenitor selectionby lateral inhibition (Carmena et al., 1998; Halfon et al., 2000).To reconcile our data and this model, we propose that the muscleDA3 CRM is only active in the DA3/D05 progenitor because itlacks some positively acting cis-elements necessary to counteractN-mediated repression of col transcription (Fig. 7A). We haveindeed previously shown that col transcription is repressedby N during the progenitor selection process (Crozatier andVincent, 1999). We also noted that a Twi-binding site is presentin the `progenitor' subdomain of the DA3 CRM (Fig. 2B and Fig. 7A).The functional importance of this site is supported by its invivo occupancy in 4- to 6-hour-old embryos when selection ofthe DA3/DO5 progenitor takes place (Sandmann et al., 2007). Together,Twi in vivo binding and the col/P2.6cl/P2.3cl expression datasuggest that Twi activity contributes to col expression in theDA3/DO5 progenitor but may not be sufficient to override N repressionof col transcription before progenitor selection. Additionalbinding sites for Twi present in the col upstream region, betweenpositions -8.7 and -8.3, are also bound by Twi in vivo (Sandmannet al., 2007) and probably contribute to the robustness of P9clexpression in progenitor cells, but the question of which cis-regulatoryelements mediate col activation in promuscular clusters remainsopen. From their Eve expression studies, Michelson and colleaguesdeveloped a computational framework to identify other FC-specificgenes (Estrada et al., 2006; Philippakis et al., 2006). Thisframework, named Codefinder, integrates transcriptome data andclustering of combinations of binding sites for five differentTFs (Pnt, dTCF, Mad, Twi and Tin). col/kn was selected by Codefinderowing to the presence of five clusters of binding sites, fourof which are located within introns (Philippakis et al., 2006).It remains to be determined which of these could be responsiblefor col activation in promuscular clusters, but it is interestingto note that another in vivo Twi-binding site in 4-6-hour-oldembryos correlates with the 3'-most cluster (Sandmann et al., 2007).In addition to Twi, conserved binding sites for Nau and Mef2are found within the DA3 CRM. The Mef2 binding site is locatedin a region required for robust DA3-muscle expression of a reportergene (Fig. 2B, Fig. 7B; and see Fig. S2 in the supplementary material).A direct control of col transcription by Mef2 during the musclefusion process is further supported by the recent finding thatMef2 binds in vivo to the col upstream region between 6 and8 hours of embryonic development (Sandmann et al., 2006).

Propagation of transcriptional identity from the founder cell to fusion-competent myoblasts
Detailed analysis of col auto-activation revealed a reiterative, two-stepprocess: import of pre-existing Col protein in the FCM nucleithat incorporate into the growing DA3 myofibre precedes activationof col transcription (Fig. 3). This process ensures that allincorporated FCM nuclei acquire the same identity. Nau is requiredfor maintaining col transcription in the DA3 muscle precursorand this control is probably direct. The presence of a putative EBF-bindingsite in the DA3 muscle CRM also correlates with the Col requirementfor maintaining its own transcription beyond the FC stage (Crozatierand Vincent, 1999). Thus, despite the failure of our assaysto detect strong Col binding to this site in vitro, it appearsto be essential for col auto-regulation in vivo. This suggeststhat in vivo binding is potentiated by one or more specificco-factor(s) present in the DA3 muscle. One co-factor is probably Nau,as the ability of Col to activate its own transcription in newly recruitedFCM is dependent upon Nau activity (Fig. 7B). Nau is not sufficient,however, as many muscles containing both Nau and Col proteinsdo not activate col transcription (Fig. 5). Interestingly, mouse EBF(also known as Ebf1 and Olf1 - Mouse Genome Informatics) andE2A (Tcfe2a - Mouse Genome Informatics), a bHLH protein of thesame subgroup as MyoD (Simionato et al., 2007), have been shownto act on the same target promoter and synergistically upregulate transcriptionof B-lymphocyte-specific genes, although no direct physical interactionbetween EBF and E2A could be found in vitro. This suggestedthat functional interaction of EBF and E2A, similar to Col andNau, requires yet another factor (O'Riordan and Grosschedl, 1999).Taking into account the restricted pattern of ectopic col activationin hs-col conditions, we hypothesised that Vg could be anothercomponent of the DA3 combinatorial identity (Bate, 1993; Frasch,1999). However, we found that Vg is not required for DA3 musclespecification, leaving open the question of which factor maybridge Col and Nau functions.

Temporal and combinatorial control of muscle identity
Unlike col or P2.6cl, P2.3cl is expressed in the DA3 FC andmuscle precursor but not the DA3/DO5 progenitor, showing thatcol transcription in the progenitor and muscle precursor isunder separate control. These two phases of col regulation areintimately linked, however, as Col is required for activatingits own transcription in the nuclei of FCM recruited by theDA3 FC. This regulatory cascade may explain how pre-patterningof the somatic mesoderm and muscle identity are transcriptionallylinked in the Drosophila embryo. As discussed above, the abilityof Col to auto-regulate depends upon the presence of Nau, anothermuscle identity TF. Col and Nau act as obligatory co-factorsfor maintenance/activation of Col expression in all nuclei ofthe DA3 muscle, thus bringing to light a clear case of combinatorialcoding of muscle identity.

Supplementary material
Supplementary material for this article is available at http://dev.biologists.org/cgi/content/full/134/24/4347/DC1

ACKNOWLEDGMENTS

We thank the Bloomington Stock Center, S. Menon and S. Abmayrfor fly stocks, D. Kiehart for antibodies, A.M. Michelson forsharing unpublished results, M. Markstein for access to FlyEnhancer version 2, J. Boyes and G. Delsol for help with generatingCol antibodies and S. Plaza and D. Cribbs for discussion. Weacknowledge the help of the Toulouse RIO Imaging platform and B.Ronsin for confocal microscopy. This work was supported by CNRS, Ministèrede la Recherche et de la Technologie, Université Paul Sabatier(grant to G. Delsol, Inserm U563 and A. Vincent) and Association Françaisecontre les Myopathies. J.E. was supported by a fellowship fromMRT.

REFERENCES

TOP
SUMMARY
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
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