1 Department of Molecular Genetics, Weizmann Institute of Science, Rehovot 76100, Israel
2 EMBL, Heidelberg, Germany
3 Department of Biology, New York University, New York, USA
*Author for correspondence (e-mail: benny.shilo{at}weizmann.ac.il)
Accepted 13 May 2002
![]() |
SUMMARY |
---|
![]() ![]() ![]() ![]() ![]() ![]() ![]() |
---|
Key words: Elbow, Noc, Zinc finger, Trachea, Branch migration, Groucho, Drosophila
![]() |
INTRODUCTION |
---|
![]() ![]() ![]() ![]() ![]() ![]() ![]() |
---|
The final structure of the tracheal tree is elaborate. Each tracheal pit gives rise to five different branches: dorsal branch (DB), dorsal trunk (DT), visceral branch (VB), lateral trunk anterior (LTa) and lateral posterior/ganglionic branch (LTp/GB). The number of cells allocated to each branch is fixed and the final structure of each branch is stereotyped, reflecting established migration routes. Within each branch, different cell types are formed from an originally equipotent population of tracheal cells (Samakovlis et al., 1996a). The cells at the termini of the branches differentiate as terminal cells that send long hollow extensions to hypoxic tissues (Guillemin et al., 1996
). Another group of specialized cells, termed fusion cells, establishes connections between branches from adjacent segments (Samakovlis et al., 1996b
; Tanaka-Matakatsu et al., 1996
).
This elaborate tracheal structure is set up by the concerted activity of multiple signaling pathways, uncovered in the past decade (reviewed by Affolter and Shilo, 2000; Zelzer and Shilo, 2000b
). The initial assignment of tracheal fates within the population of ectodermal cells is driven by the localized expression of the Trachealess and Drifter transcription factors (Anderson et al., 1995
; Wilk et al., 1996
; Llimargas and Casanova, 1997
; Zelzer and Shilo, 2000a
). Persistent expression of these genes in the trachea provides a cell context for other signals that impinge on the trachea.
Prior to the onset of tracheal migration, the precise number of cells must be allocated to each future branch. Several signaling pathways contribute to this decision, and in many cases parallel inputs from different pathways are responsible for the assignment of a particular branch fate (Wappner et al., 1997; Vincent et al., 1998
; Llimargas, 2000
; Llimargas and Lawrence, 2001
; Chihara and Hayashi, 2000
; Glazer and Shilo, 2001
).
The process of migration is guided by the FGF pathway. All tracheal cells express the FGF receptor, Breathless (Btl) (Glazer and Shilo, 1991; Klämbt et al., 1992
). The ligand, Branchless (Bnl), is expressed locally in adjacent ectodermal or mesodermal cells (Sutherland et al., 1996
). This restricted ligand presentation is responsible for guided migration. In addition, as the branches elongate, the levels of Btl activation determine the fate of the cells as terminal or fusion cells. Additional accessory guidance systems are present, such as the presence of a mesodermal cell expressing Hunchback (Hb) that assists the migration of the dorsal trunk cells (Wolf and Schuh, 2000
).
Morphogenesis of the tracheal system is determined by highly coordinated signaling events, which are restricted in both space and time (Affolter and Shilo, 2000; Zelzer and Shilo, 2000b
). This prompted us to search for new genes regulating tracheal development using the EP misexpression screen (Rorth, 1996
; Rorth et al., 1998
). We used the midline- and tracheal-specific btl-Gal4 driver (Shiga et al., 1996
), and screened the collection of EP lines for those that will give rise to lethality because of aberrant development of the tracheal system, or other tissues expressing btl-Gal4. Known genes that regulate tracheal patterning, such as dpp, bnl, rhomboid and escargot were scored, validating the specificity of the approach. In addition, this screen identified new genes that were not previously known to be involved in patterning the trachea.
We present the analysis of the elB gene encoding a conserved nuclear protein with a single zinc finger. ElB misexpression in the trachea gave rise to loss of the visceral branch and expansion of the dorsal branch, while a mutation in the gene resulted in defective migration in the lateral and dorsal branches. These phenotypes are consistent with the restricted expression of elB in the lateral trunk and dorsal branch. While the elB mutant tracheal phenotypes are reminiscent of defects in Dpp signaling, the two inputs are independent. ElB thus defines a parallel pathway that determines the identity of the lateral trunks and dorsal tracheal branches. A similar phenotype was observed in mutations for the noc gene, which encodes a protein homologous to ElB. We show that the two proteins associate with each other, suggesting that they function as a complex. In addition. ElB associates with the Groucho protein, implying that the ElB/Noc complex can repress the expression of target genes. Indeed, in elB or noc mutants, expanded expression of tracheal branch-specific or cell-specific genes was observed.
![]() |
MATERIALS AND METHODS |
---|
![]() ![]() ![]() ![]() ![]() ![]() ![]() |
---|
The following markers for gene expression in specific tracheal branches were used: l(2)01351, which expresses lacZ in the visceral branch and in pairs of cells in the dorsal trunk; and kni-lacZ (2.2 KI) inserted on the third chromosome (provided by R. Schuh), which is expressed in the dorsal branch, visceral branch and lateral trunks.
To test the relationship between the Dpp pathway and ElB, the following lines were used: tkvII/CyO (provided by K. Basler), UAS-tkv* (provided by S. Cohen) and UAS-knrl (provided by R. Schuh).
Sequences analysis
Protein sequences were scanned for homologies and conserved domains by protein BLAST (BLASTP) and by SMART (http://smart.embl-heidelberg.de/) and InterProScan (http://www.ebi.ac.uk/interpro/scan.html). Multiple sequence alignments were made by PIMA protocol in the BCM Search Launcher (http://searchlauncher.bcm.tmc.edu/multi-align/multi-align.html). elB cDNA GenBank Accession Number, AY115567.
Antibodies and in situ hybridization
Rat anti-ElB was generated by injecting full length, His-tagged, recombinant protein expressed in a pRSET vector. To visualize tracheal nuclei and lumen we used rat anti-Trh and monoclonal 2A12. Rabbit anti-Sal antibody (provided by R. Schuh), and rabbit anti-ß-gal (Cappel) or mouse anti-ß-gal (Promega) were also used. Rabbit anti-pSmad1 antibodies (provided by P. ten Dijke) were used at a dilution of 1/200. Secondary antibodies were purchased from Jackson ImmunoResearch.
DIG-labeled RNA antisense probes were prepared from elB or noc cDNAs, and processed and visualized according to standard protocols.
GST pull-down
The following GST fusion constructs were generated from elB: pGEX-4T3 containing ElB-69-553aa (generated by cloning an XhoI fragment). pGEX-4T3 containing ElB-287-553 amino acids (generated by cloning the 3' BamHI fragment). pGEX-4T3 containing ElB-287-480 amino acids (generated from the 3' BamHI-NotI fragment). The Noc GST fusion pGEX-4T3 contains 297-396 amino acids (generated from the EcoRV-NotI fragment). All GST fusion constructs were purified on Glutathione-agarose (Sigma) by standard procedures. ElB, Noc, CtBP and Groucho were labeled with 35S-methionine in vitro by translation in TnT T7RNA polymerase-coupled reticulocyte lysate system (Promega) according to manufacturers instructions. groucho and CtBP cDNAs were provided by Z. Paroush.
GST pull-downs were performed in 10 mM Tris (pH 7.0), 150 mM NaCl, 0.1% Triton X-100 buffer. After 2 hours binding, beads were washed five times with the same buffer for 2 minutes each, followed by an additional 30 minute wash with 10 mM Tris (pH 7.0), 300 mM NaCl, 0.1% Triton X-100 buffer. Samples were separated on a 10% acrylamide gel by SDS-PAGE, fixed for 30 minutes in acetic acid:water:isopropanol (10:65:25) and washed for 15 minutes in Amplify solution (Amersham), prior to exposure.
![]() |
RESULTS |
---|
![]() ![]() ![]() ![]() ![]() ![]() ![]() |
---|
|
To obtain a finer resolution, we followed molecular markers for the different branches. By using the l(2)01351 enhancer trap line that marks the visceral branch cells, we show that this marker is not expressed in the cells remaining in the transverse connective following ElB misexpression. Overexpression indeed abolished expression of a gene normally marking the visceral branch cell fate (Fig. 2A,B).
|
In ElB misexpression embryos, several cells normally assigned to the dorsal trunk appear to be migrating into the dorsal branch, thus increasing the cell number in that branch. This suggested that there may also be a defect in specifying the dorsal trunk fate. Therefore, we followed a dorsal trunk marker, Spalt (Sal), in embryos misexpressing ElB. Sal is a transcription factor that is specifically expressed in the dorsal trunk cells and determines their identity (Kuhnlein and Schuh, 1996). Ectopic ElB expression abolished all Sal expression in the trachea (Fig. 2E,F). Surprisingly, this did not lead to an absence of the dorsal trunk, which is typical of sal mutant embryos, presumably because the btl-Gal4 driver induced the accumulation of ElB and abolishment of Sal expression after execution of the normal Sal function in the dorsal trunk.
These experiments suggest that ElB expression must be excluded from the dorsal trunk and visceral branch, in order to specify their proper identities.
Elbow is a single zinc-finger protein
Plasmid rescue of the EP(2)2039 element showed that it is inserted at chromosomal position 35B, previously known as the elbow-noc (elB-noc) region (Davis et al., 1990; Davis et al., 1997
; Ashburner et al., 1999
). The EP line is inserted 965 bp upstream to the 5' UTR and 1365 bp upstream to the translation start site of elB, and is homozygous viable. As no publicly available ESTs were found, we screened an embryonic cDNA library with the EP(2)2039 genomic rescue fragment. Three positive clones were sequenced and analyzed, all of them were 2550 bp and encoded a protein of 553 amino acids. The cDNA translation shows that there is a different exon-intron structure compared with both the published GeneScan predicted DS06238.3 (Ashburner et al., 1999
), and to CG4220 in the current GadFly genomic annotation (http://hedgehog.lbl.gov:8001/cgi-bin/annot/query/).
BLAST analysis of the cDNA sequence was performed and shows that ElB belongs to the Sp1 transcription factor family. However, it contains a single zinc finger (C2H2 type), while Sp1 transcription factors generally posses several zinc fingers. Antibody staining of ElB in embryos overexpressing elB indeed showed a nuclear localization pattern (Fig. 1D). The closest homolog of ElB is the Drosophila Noc protein, which shares 50% identity (Cheah et al., 1994). It has previously been reported that Noc contains two zinc fingers, but the algorithms we used detect only one zinc finger. The noc gene is located in the same chromosomal region at a distance of 82 kb from elB, suggesting that it arose by a gene duplication event.
A human protein termed AK024361, which is localized to 8p11.2, and a putative transcript from chromosome 10 show a high degree of similarity to ElB and Noc proteins. Alignment of these four proteins allowed identification of additional conserved domains (Fig. 3). In the N terminus there is a putative activation domain, while a proline- and tyrosine-rich domain is located in the C terminus. In addition, there is a cysteine-rich domain in the middle of ElB protein. Between the activation domain and Cysteine-rich domain are several stretches of Alanine repeats. Previous studies suggested that Noc functions as a repressor of transcription due to the high amount of the A-repeats (Cheah et al., 1994). A putative FKPY Groucho-binding motif (Zhang et al., 2001
; Hasson et al., 2001
) is also found in all four proteins (see below).
|
|
elbow mutant phenotype
To determine the role of ElB in the branches where it is normally expressed, analysis of mutations in the elB locus was carried out. Several mutant fly lines in the elB region are available; however, they are not precisely mapped. In order to create a line with a specific elB mutation, we excised the EP element, using a Delta 2-3 transposase. Only one lethal excision line (termed elBd47) showed rearrangements in Southern blot analysis in the region of EP2039. Inverse PCR of the rearranged genomic fragment and sequencing provided the following molecular details. The EP2039 element was deleted. All sequences between EP2039 insertion site and elB were intact, while on the other side sequences of the transposable yoyo element were identified. Further Southern analysis indicated a deletion of the genomic sequence in the region upstream to EP2039 insertion. Therefore, it is possible that an inversion coupled to a deletion of sequences upstream to EP2039 has taken place. elBd47 was lethal over Df(2L)noc10 and over the smaller deficiency Df(2L)fn2, uncovering 35A3-35B2. While elBd47 did not remove genomic regions containing the elB transcribed region, it was nevertheless allelic to the EMS-induced viable mutation elB1, which displayed the typical smaller wing phenotype. It is thus possible that crucial transcriptional regulatory sequences of elB were removed in elBd47.
Homozygous elBd47 embryos displayed defects in tracheal development. Below, we describe these defects and demonstrate that they can be specifically rescued by expression of elB. In all segments, there was no migration of the lateral trunk anterior, and the ganglionic branches were shorter. The cells, which failed to migrate into the lateral trunk remained in the transverse connective. The number of cells that form the dorsal trunk and visceral branch did not change (Fig. 5). Dorsal branch migration was also impaired, and failure of dorsal branch fusion was observed at stage 16. Cell counts of dorsal branch cells in the mutant embryos showed a considerable number of branches with only three to four cells (Fig. 1E). In some of the segments, the dorsal branch cells migrated aberrantly, and laterally adjacent branches fused (Fig. 5H,J). The same tracheal phenotype was observed in embryos homozygous for the Df(2L)fn2 deficiency, as well as trans-heterozygotes of elBd47 over Df(2L)fn2 (not shown), demonstrating that elBd47 is a null mutation.
|
elbow mutants display normal Mad phosphorylation
The tracheal phenotype of elB mutants is reminiscent of defects arising when signaling by the Dpp pathway is blocked (e.g. in thickveins mutant embryos) (Affolter et al., 1994; Vincent et al., 1997
; Wappner et al., 1997
). Most notable is the stalled migration of the lateral trunk anterior, the ganglionic branch and the dorsal branch. Dpp is expressed at stage 11 in two ectodermal stripes: the dorsal stripe is restricted to a single row of the dorsal-most ectodermal cells, and is positioned several cells away from the dorsal edge of the tracheal pit. The ventrolateral stripe of Dpp expression abuts the ventral side of the tracheal pit (Vincent et al., 1997
).
Activation of the Tkv/Punt receptors by Dpp leads to the phosphorylation of the Mad protein, which forms a heterodimer with Medea and translocates to the nucleus to trigger transcription (Raftery and Sutherland, 1999). Antibodies specifically recognizing the C-terminal phosphorylated form of Smad1 were shown to also recognize the phosphorylated form of Drosophila Mad (Persson et al., 1998
; Tanimoto et al., 2000
; Dorfman and Shilo, 2001
). We used these antibodies to follow Dpp signaling in the trachea in wild-type and elB mutant embryos.
In wild-type embryos, pMad is observed in the tracheal pits beginning at early stage 11, when Dpp is expressed in two stripes in the dorsal and ventrolateral ectoderm (Fig. 6A). Dpp activation subdivides the tracheal pit into three parts: the activated dorsal and ventral domains and the central region, which is not activated by Dpp. The number of cells in which pMad is generated in the ventral domain of the pit is significantly larger than the number of tracheal cells displaying pMad in the dorsal domain. As the dorsal stripe of Dpp is positioned several cell diameters above the tracheal pit, the diffusion of Dpp reaches and activates only approx. five tracheal cells. This corresponds to the number of cells that will be recruited to the dorsal branch.
|
The pMad patterns allowed us to determine directly whether the reception of Dpp signaling is compromised in elB mutants. elBd47 embryos were stained with the pMad antibody, and identified by the stalled migration of the lateral trunk anterior. The number of dorsal and ventral cells displaying pMad in the pit at stage 11/12 is comparable with wild-type embryos (Fig. 6C,D). ElB is thus not required for normal signaling by the Dpp pathway.
ElB functions in parallel to Dpp in the trachea
ElB could be required downstream of pMad, for the induction of Dpp-target genes. Expression of kni, which encodes a zinc-finger transcription factor, is induced by the activated Tkv/Punt receptors (Vincent et al., 1997; Chen et al., 1998
). We used a kni-lacZ transgene to follow the dependence of kni expression on ElB. Overexpression of ElB did not alter the expression pattern of kni (Fig. 2D). Likewise, in elB mutants, the expected number of dorsal branch cells retained kni expression (Fig. 7D). However, while normally the kni-expressing cells segregate completely from the dorsal trunk into the dorsal branch, in the elB mutant, several cells were retained within the dorsal trunk. This may be a reflection of failure of the cells destined to form the dorsal branch to lose their identity completely as dorsal trunk cells. Indeed, when expression of the dorsal trunk marker Sal was examined, we observed residual Sal in all the kni-expressing cells that remained within the dorsal trunk, and in some of the cells forming the dorsal branch (Fig. 7C,D). Thus, Kni is not sufficient to repress Sal expression, and requires cooperation with ElB for complete repression.
|
The combined effects of ElB misexpression and uniform activation of Tkv in the trachea could be manifested in cell fate changes leading to excess LTa cells. Following misexpression of only ElB or activated Tkv, the number of LTa cells was unchanged, while the typical visceral branch and dorsal branch abnormalities were observed (Fig. 7G,H, respectively). However, misexpression of both constructs also lead to changes in LTa cell fates (Fig. 7G), as extra cells were recruited into this branch.
noc mutants display similar tracheal phenotypes
The similarity between ElB and Noc proteins prompted us to examine the role of Noc in tracheal development. In situ hybridization shows that noc is expressed from stage 4 in the embryonic termini, and at stage 5/6 in ectodermal stripes. At stage 11, noc is expressed in the invaginating tracheal pits, while from stage 13, noc is expressed ubiquitously (Fig. 8A-D) (Cheah et al., 1994). As noc expression is not spatially restricted, it is not surprising that no tracheal phenotypes were observed after Noc misexpression by btl-Gal4/EP2000 (Fig. 8E). Higher levels of induction of noc expression (using UAS-noc), did not abolish the visceral branches, but their direction of migration was occasionally misrouted (not shown). In addition, misexpression of both ElB and Noc in the trachea did not generate a phenotype that is more severe than the one produced by misexpression of ElB alone.
|
Association of ElB and Noc
In view of the overlapping tracheal expression patterns and the previously reported genetic interactions (Davis et al., 1997), it is possible that the ElB and Noc proteins form a heterodimeric complex. As each protein contains only a single zinc finger, a heterodimer may provide the appropriate number of zinc fingers for DNA binding. GST pull-down experiments were carried out using GST fusions to full-length constructs of the ElB protein, as well as to fragments of the ElB protein. Association with in vitro translated full-length ElB or Noc was examined. Indeed, GST-ElB was capable of associating with Noc. In addition, GST-ElB was also capable of associating with ElB, demonstrating that ElB can form homodimers as well as heterodimers with Noc (Fig. 9). Truncated constructs of ElB show that its C-terminal region, which contains the Cysteine-rich and zinc-finger domains, is sufficient for these interactions. The specificity of these interactions was demonstrated by the inability of GST alone, or of GST fused to an irrelevant 60 kDa human protein to associate with labeled ElB.
|
The Groucho protein is known to mediate long-range transcriptional repression, and to associate with DNA-binding proteins bearing a number of motifs, including FKPY. This sequence is conserved in ElB, Noc and the two human homologs. We thus tested the capacity of ElB to associate with Groucho. Indeed, specific association was detected (Fig. 9). CtBP promotes short-range repression and is known to associate with DNA-binding proteins containing the PxDLSxR/K/H motif (Zhang et al., 2001). Such a motif is not found in ElB or Noc, and the GST-ElB fusion protein shows only negligible precipitation of labeled CtBP (not shown). This result strongly suggests that the ElB/Noc complex represses transcription of target genes directly, by recruiting Groucho to these sites.
![]() |
DISCUSSION |
---|
![]() ![]() ![]() ![]() ![]() ![]() ![]() |
---|
ElB overexpression was shown to repress expression of genes such as the visceral branch marker and sal (Fig. 2). Conversely, absence of ElB resulted in expanded expression of Sal to the dorsal branch, and noc mutants displayed failure to repress SRF expression in the fusion cells of the dorsal branch (Figs 7, 8), suggesting that ElB functions as a repressor of gene expression. One piece of evidence strongly indicates that the ElB/Noc complex indeed functions directly to repress the expression of target genes. Both Drosophila proteins, as well as the human homologs, contain the FKPY motif (Fig. 3), which was shown to be sufficient for interactions with Groucho (Zhang et al., 2001; Hasson et al., 2001
). Indeed, GST pull-down experiments demonstrated that ElB can associate with Groucho (Fig. 9). It is interesting to note that another Sp1 homolog, Huckebein (Hkb), was previously shown to recruit Groucho through the FRPW motif (Goldstein et al., 1999
). The ElB/Noc complex may thus serve to recruit the Groucho protein to specific target sites on the DNA, and repress the expression of distinct genes. Future identification of target genes will determine if ElB/Noc can also facilitate induction of certain genes.
Roles of ElB/Noc in the trachea
Expression of ElB is confined to distinct tracheal branches from stage 12, namely the dorsal branch and lateral trunks (Fig. 4). This restricted expression is instructive for the future fate and migration pattern of these branches. When misexpressed in other branches, ElB abolishes the migration of the visceral branch and eliminates the expression of a visceral branch marker. It also represses expression of Sal, a protein that defines the dorsal trunk identity (Figs 1, 2). ElB was also able to divert several cells from the dorsal trunk fate into a dorsal branch.
In the tracheal branches where elB is normally expressed, it has an essential role. In elB null mutants, fewer cells join the dorsal branch, and these branches migrate abnormally. In addition, the cells normally forming the lateral trunk anterior remain in the transverse connective, and the ganglionic branches are stalled. We can try to interpret these phenotypes with the repressive activity of the ElB/Noc complex in mind.
It is possible that in the dorsal branch, the complex represses expression of genes that confer dorsal trunk identity such as sal. A similar paradigm was previously shown for the Dpp pathway. kni expression in the dorsal branch is induced by the Dpp pathway. Kni can bind the sal promoter and repress expression of the gene (Chen et al., 1998). In elB mutants expression of dorsal trunk genes extends to the dorsal branch and partially converts the identity of these cells to a dorsal trunk fate. Similarly, in the lateral trunk the ElB/Noc complex may be required to repress the expression of genes conferring visceral branch identity. In elB mutants, the expanded expression of visceral branch- and dorsal trunk-specific genes into the lateral trunk may thus abolish or stall the migration of the lateral trunk and ganglionic branches. Subsequently, ElB expression is confined to a specific cell within the dorsal branch, namely the fusion cell. In noc mutants the expression of SRF in the dorsal branch expanded to the fusion cell (Fig. 8H). One way to interpret the expanded expression of SRF is by loss of direct repressive activity of ElB/Noc in the fusion cell. A model for the role of ElB in determination of branch fates is shown in Fig. 10.
|
Parallel activity of ElB/Noc and the Dpp pathway
The tracheal defects observed in elB mutants are reminiscent of tracheal defects in tkv mutant embryos, where signaling of the Dpp pathway is blocked (Affolter et al., 1994). However, ElB appears to function in parallel to the Dpp pathway. Phosphorylation of Mad and induction of kni expression, which mark the activity of the Dpp pathway, are normal in elB mutants. Conversely, ElB expression is independent of Dpp/Tkv activation (Figs 6, 7). The possibility that Dpp signaling directs a post-translational modification of ElB/Noc has not been ruled out. Nevertheless, the available data suggests that generation of the dorsal branch, and migration of the lateral trunk anterior and ganglionic branch, require both the input from Dpp signaling and the expression of ElB/Noc.
It is not known yet how activation of distinct tracheal cells in the dorsal and ventral region of the tracheal pit by Dpp, as visualized by pMad accumulation, contributes to the capacity of these cells to form the dorsal and lateral branches, respectively. Activation by Dpp induces expression of target genes such as kni in these compartments. Kni in turn was shown to repress expression of dorsal-trunk genes like sal.
How are the ElB/Noc and Dpp signals integrated in the trachea? One possibility is that they impinge on different target genes. ElB/Noc repress expression of visceral branch or dorsal trunk genes, while the Dpp signal induces the expression of target genes in the same cells. The combined activity of the two pathways will determine the set of branch-specific genes expressed by these cells. The final identity of each branch is likely to be a result of inputs from different pathways, which contribute to the expression of branch-specific genes and to the repression of other genes. This is exemplified most clearly when monitoring kni expression in the dorsal branch of elB mutant embryos. While the correct number of cells are induced by the Dpp pathway and express kni, some of these cells are stalled in the dorsal trunk in the absence of ElB (Fig. 7D). It is also demonstrated by the fact that only the combined activity of ElB and activated Tkv was capable of inducing an excess of LTa cells (Fig. 7I). ElB/Noc and Kni also cooperate in the repression of common target genes. Complete repression of sal in the dorsal branch cells requires both complexes, as evidenced by the expanded expression of Sal in elB-mutant embryos (Fig. 7C).
Future knowledge regarding the nature of these branch-specific target genes should provide insights into the mechanism that regulate branch-specific fates. These genes may encode adhesion molecules or membrane receptors that allow responses to different sets of external guiding cues. This system could provide further migrational specificity, superimposed on the common Branchless signal guiding the migration of all tracheal branches. Furthermore, it may determine the stereotyped number of cells recruited into each tracheal branch.
Regulation of ElB/Noc
The similarity in the phenotypes of elB and noc mutants, the genetic interaction between the mutants, and the complex formed between the two proteins, strongly suggest that these proteins carry out their biological roles as a complex. However, the two genes are regulated differently in the embryo. noc is broadly expressed and overexpression of the protein does not give rise to a tracheal phenotype, suggesting that spatial and temporal regulation of activity relies on elB expression. The restricted expression of elB is essential, as elB misexpression gives rise to deleterious phenotypes in the trachea. We do not know if additional tiers of regulation, such as inputs from signaling pathways or phosphorylation, also impinge on the complex.
Expression of elB is initially observed in all tracheal cells, suggesting that it is under the control of Trachealess and Drifter, which confer tracheal identity. However, at stage 12 expression of elB becomes excluded from the central part of the pit. It is possible that the restricted pattern of elB expression is thus a combination of induction by general tracheal transcription factors, and repression of expression in the future dorsal trunk and visceral branch. The signals leading to this repression are not known. The EGF receptor pathway is activated in the central domain of the tracheal placodes (Wappner et al., 1997). However, when the activity of this pathway was abolished in Star mutants, elB expression remained unchanged (not shown).
It will be interesting to find out the function the ElB/Noc complex in other tissues. In noc mutant embryos, defects in migration of cells from the procephalic lobe were observed (Cheah et al., 1994). Expression of elB is not restricted to the trachea, and is also observed in the wing imaginal disc and the adult photoreceptors (S. Cohen and C. Desplan, personal communication). In accordance with the roles of the ElB/Noc complex in the trachea, it is likely that in the above tissues the same complex will be essential for determination of cell fates, by repressing and possibly also inducing critical target genes.
In conclusion, using a tracheal misexpression screen we have identified two proteins that form a complex, and participate in the determination of specific tracheal branch fates. ElB/Noc define a parallel input to Dpp signaling, demonstrating that convergence of several signals contributes to the robust determination of branch-specific cell fates, and to the refinement of these fates.
![]() |
ACKNOWLEDGMENTS |
---|
![]() |
REFERENCES |
---|
![]() ![]() ![]() ![]() ![]() ![]() ![]() |
---|
Affolter, M., Nellen, D., Nussbaumer, U. and Basler, K. (1994). Multiple requirements for the receptor serine/threonine kinase thick veins reveal novel function of TGFb homologs during Drosophila embryogenesis. Development 120, 3105-3117.
Affolter, M. and Shilo, B.-Z. (2000). Genetic control of branching morphogenesis during Drosophila tracheal development. Curr. Opin. Cell Biol. 12, 731-735.[Medline]
Anderson, M. G., Perkins, G. L., Chittick, P., Shrigley, R. J. and Johnson, W. A. (1995). drifter, a Drosophila POU-domain transcription factor, is required for correct differentiation and migration of tracheal cells and midline glia. Genes Dev. 9, 123-137.[Abstract]
Ashburner, M., Misra, S., Roote, J., Lewis, S. E., Blazej, R., Davis, T., Doyle, C., Galle, R., George, R., Harris, N. et al. (1999). An exploration of the sequence of a 2.9-Mb region of the genome of Drosophila melanogaster: the Adh region. Genetics 153, 179-219.
Cheah, P. Y., Meng, Y. B., Yang, X., Kimbrell, D., Ashburner, M. and Chia, W. (1994). The Drosophila l(2)35Ba/nocA gene encodes a putative Zn finger protein involved in the development of the embryonic brain and the adult ocellar structures. Mol. Cell. Biol. 14, 1487-1499.[Abstract]
Chen, C. K., Kuhnlein, R. P., Eulenberg, K. G., Vincent, S., Affolter, M. and Schuh, R. (1998). The transcription factors KNIRPS and KNIRPS RELATED control cell migration and branch morphogenesis during Drosophila tracheal development. Development 125, 4959-4968.
Chihara, T. and Hayashi, S. (2000). Control of tracheal tubulogenesis by wingless signaling. Development 127, 4433-4442.
Davis, T., Ashburner, M., Johnson, G., Gubb, D. and Roote, J. (1997). Genetic and phenotypic analysis of the genes of the elbow-no-ocelli region of chromosome 2L of Drosophila melanogaster. Hereditas 126, 67-75.[Medline]
Davis, T., Trenear, J. and Ashburner, M. (1990). The molecular analysis of the el-noc complex of Drosophila melanogaster. Genetics 126, 105-119.
Dorfman, R. and Shilo, B.-Z. (2001). Biphasic activation of the BMP pathway patterns the Drosophila embryonic dorsal region. Development 128, 965-972.
Glazer, L. and Shilo, B.-Z. (1991). The Drosophila FGF-R homolog is expressed in the embryonic tracheal system and appears to be required for directed tracheal cell extension. Genes Dev. 5, 697-705.[Abstract]
Glazer, L. and Shilo, B.-Z. (2001). Hedgehog signaling patterns the tracheal branches. Development 128, 1599-1606.
Goldstein, R. E., Jimenez, G., Cook, O., Gur, D. and Paroush, Z. (1999). Huckebein repressor activity in Drosophila terminal patterning is mediated by Groucho. Development 126, 3747-3755.
Guillemin, K., Groppe, J., Ducker, K., Treisman, R., Hafen, E., Affolter, M. and Krasnow, M. A. (1996). The pruned gene encodes the Drosophila serum response factor and regulates cytoplasmic outgrowth during terminal branching of the tracheal system. Development 122, 1353-1362.
Hasson, P., Muller, B., Basler, K. and Paroush, Z. (2001). Brinker requires to corepressors for maximal and versatile repression in Dpp signalling. EMBO J. 20, 5725-5736.
Klämbt, C., Glazer, L. and Shilo, B.-Z. (1992). breathless, a Drosophila FGF receptor homolog, is essential for migration of tracheal and specific midline glial cells. Genes Dev. 6, 1668-1678.[Abstract]
Kuhnlein, R. P. and Schuh, R. (1996). Dual function of the region-specific homeotic gene spalt during Drosophila tracheal system development. Development 122, 2215-2223.
Llimargas, M. and Casanova, J. (1997). ventral veinless, a POU domain transcription factor, regulates different transduction pathways required for tracheal branching in Drosophila. Development 124, 3273-3281.
Llimargas, M. (2000). Wingless and its signaling pathway have common and separate functions during tracheal development. Development 127, 4407-4417.
Llimargas, M. and Lawrence, P. (2001). Seven Wnt homologues in Drosophila: A case study of developing trachea. Proc. Natl. Acad. Sci. USA 98, 14487-14492.
Manning, G. and Krasnow, M. A. (1993). Development of the Drosophila Tracheal System. In The Development of Drosophila melanogaster (ed. M. Bate and A. Martinez-Arias), pp. 609-685. Cold Spring Harbor, New York: Cold Spring Harbor Laboratory Press.
Persson, U., Izumi, H., Souchelnytskyi, S., Itoh, S., Grimsby, S., Engstrom, U., Heldin, C. H., Funa, K. and ten Dijke, P. (1998). The L45 loop in type I receptors for TGF-beta family members is a critical determinant in specifying Smad isoform activation. FEBS Lett. 434, 83-87.[Medline]
Raftery, L. A. and Sutherland, D. J. (1999). TGF-beta family signal transduction in Drosophila development: from Mad to Smads. Dev. Biol. 210, 251-268.[Medline]
Rorth, P. (1996). A modular misexpression screen in Drosophila detecting tissue-specific phenotypes. Proc. Natl. Acad. Sci. USA 93, 12418-12422.
Rorth, P., Szabo, K., Bailey, A., Laverty, T., Rehm, J., Rubin, G. M., Weigmann, K., Milan, M., Benes, V., Ansorge, W. and Cohen, S. M. (1998). Systematic gain-of function genetics in Drosophila. Development 125, 1049-1057.
Samakovlis, C., Hacohen, N., Manning, G., Sutherland, D. C., Guillemin, K. and Krasnow, M. A. (1996a). Development of the Drosophila tracheal system occurs by a series of morphologically distinct but genetically coupled branching events. Development 122, 1395-1407.
Samakovlis, C., Manning, G., Steneberg, P., Hacohen, N., Cantera, R. and Krasnow, M. A. (1996b). Genetic control of epithelial tube fusion during Drosophila tracheal development. Development 122, 3531-3536.
Shiga, Y., Tanaka-Matakatsu, M. and Hayashi, S. (1996). A nuclear GFP/b-galactosidase fusion protein as a marker for morphogenesis in living Drosophila. Dev. Growth Differ. 38, 99-106.
Sutherland, D., Samakovlis, C. and Krasnow, M. A. (1996). branchless encodes a Drosophila FGF homolog that controls tracheal cell migration and the pattern of branching. Cell 87, 1091-1101.[Medline]
Tanaka-Matakatsu, M., Uemura, T., Oda, H., Takeichi, M. and Hayashi, S. (1996). Cadherin-mediated cell adhesion and cell motility in Drosophila trachea. Development 122, 3697-3705.
Tanimoto, H., Itoh, S., ten Dijke, P. and Tabata, T. (2000). Hedgehog creates a gradient of DPP activity in Drosophila wing imaginal discs. Mol. Cell 5, 59-71.[Medline]
Vincent, S., Ruberte, E., Grieder, N. C., Chen, C.-K., Haerry, T., Schuh, R. and Affolter, M. (1997). DPP controls tracheal cell migration along the dorsoventral body axis of the Drosophila embryo. Development 124, 2741-2750.
Wappner, P., Gabay, L. and Shilo, B.-Z. (1997). Interactions between the EGF receptor and Dpp pathways establish distinct cell fates in the tracheal placodes. Development 124, 4707-4716.
Wilk, R., Weizman, I. and Shilo, B.-Z. (1996). trachealess encodes a bHLH-PAS protein that is an inducer of tracheal cell fates in Drosophila. Genes Dev. 10, 93-102.[Abstract]
Wolf, C. and Schuh, R. (2000). A single mesodermal cell guides outgrowth of ectodermal tubular structures in Drosophila. Genes Dev. 14, 2140-2145.
Zelzer, E. and Shilo, B.-Z. (2000a). Interaction between the bHLH-PAS protein Trachealess and the POU-domain protein Drifter, specifies tracheal cell fates. Mech. Dev. 91, 163-173.[Medline]
Zelzer, E. and Shilo, B.-Z. (2000b). Cell fate choices in Drosophila tracheal morphogenesis. BioEssays 22, 219-226.[Medline]
Zhang, H., Levine, M. and Ashe, H. L. (2001). Brinker is a sequence-specific transcriptional repressor in the Drosophila embryo. Genes Dev. 15, 261-266.