1 Program in Genetics,
2 Molecular and Cellular Biology Program, Department of Genome Sciences, Box 357730, University of Washington, Seattle, WA 98195-7730, USA
*Author for correspondence (e-mail: berg{at}gs.washington.edu)
Accepted 6 February 2002
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SUMMARY |
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Key words: Drosophila melanogaster, Dorsal-ventral polarity, Follicle cell, Cell migration, Epithelial morphogenesis, Oogenesis, Ras, Egfr, pipe, E-cadherin
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INTRODUCTION |
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In Drosophila melanogaster, the Ras signaling cassette is the major effector of RTK signaling during development, transducing signals from the epidermal growth factor receptor (Egfr), fibroblast growth factor receptor (FGFR/Breathless), Torso, and Sevenless RTKs (for a review, see Wassarman et al., 1995). Sophisticated genetic experiments have revealed the developmental functions for RTK/Ras signaling, including terminal patterning, ventral ectoderm patterning, photoreceptor development and specification, cell growth, and tracheal branching (for reviews, see Schweitzer and Shilo, 1997
; Wassarman et al., 1995
). In the Drosophila ovary, Ras functions downstream of Egfr to induce dorsal cell fate in the follicular epithelium (Schnorr and Berg, 1996
).
Dorsoventral patterning of the eggshell and embryo occurs during oogenesis and is accomplished by cell-cell communication between the somatic follicular epithelium and the underlying germline cells (for reviews, see Nilson and Schüpbach, 1999; Van Buskirk and Schüpbach, 1999
). Dorsoventral symmetry is broken midway through oogenesis, when the oocyte nucleus (and associated gurken (grk) mRNA) migrates from its posterior location to a random position at the anterior cortex of the oocyte (Roth et al., 1999
). This newly relocalized source of the germline ligand Gurken (TGF
) activates Egfr in overlying somatic follicle cells, establishing a dorsal fate that is revealed by asymmetric expression of target genes along the dorsoventral axis.
Dorsoventral patterning of the follicle cells produces dorsoventral asymmetry in two distinct structures: the eggshell, secreted by the follicle cells, and the embryo, which develops within the eggshell following oviposition. To pattern the eggshell, Gurken activates Egfr in the dorsal-most follicle cells, triggering an amplification and spatial refinement of Egfr activity that can be monitored by detecting the active form of MAP kinase (Peri et al., 1999). The genes spitz, vein and rhomboid function in the follicle cells to amplify dorsal Egfr activity; then argos, which encodes an Egfr inhibitory ligand, downregulates Egfr activity on the dorsal midline, refining a single broad dorsal peak of Egfr activity into two dorsolateral peaks (Wasserman and Freeman, 1998
). In addition to this elaborate dorsoventral patterning process, anterior Decapentaplegic (Dpp) signaling specifies the anterior-posterior dimensions of the two dorsolateral regions of peak Egfr activity (Peri and Roth, 2000
). During the final stages of oogenesis, these two anterior, dorsolateral groups of cells undergo morphogenesis and secrete the chorion that constitutes the two dorsal respiratory appendages of the eggshell.
Like eggshell patterning, dorsoventral patterning of the embryo is initiated by dorsal Gurken signaling (for a review, see Anderson, 1998). Egfr activity in dorsal follicle cells of the egg chamber represses transcription of pipe (pip), which encodes a putative glycosaminoglycan-modifying enzyme that functions together with the products of the ubiquitously expressed genes nudel and windbeutel to initiate an extracellular proteolytic cascade that culminates in the activation of the Toll receptor in the embryonic plasma membrane. Ventral Toll signaling induces nuclear translocation of the NF-
B/Rel homolog Dorsal in a gradient: highest in ventral embryonic nuclei to undetectable in dorsal nuclei. This gradient of nuclear Dorsal determines the zones of expression for zygotic patterning genes along the dorsoventral axis (for a review, see Rusch and Levine, 1996
). Importantly for this work, loss-of-function and ectopic-expression data indicate that pipe is both necessary and sufficient to induce embryonic ventral cell fates (Nilson and Schüpbach, 1998
; Sen et al., 2000
; Sen et al., 1998
).
One outstanding mystery of dorsoventral patterning is that while pipe is expressed in only the ventral-most third of the follicular epithelium (Sen et al., 1998), the expression of genes activated by Gurken/Egfr signaling is detected in only the dorsal-most third of the epithelium (Ghiglione et al., 1999
; Jordan et al., 2000
; Reich et al., 1999
; Ruohola-Baker et al., 1993
). How, then, is pipe repressed in the middle, or lateral third of the epithelium? In one hypothesis, dorsal anterior Gurken/Egfr signaling induces secretion of a second morphogen that represses pipe at a distance (Jordan et al., 2000
). Alternatively, Pai and colleagues (Pai et al., 2000
) propose that Gurken directly defines the pipe repression domain.
Since eggshell and embryonic dorsoventral patterning are initiated by the same signaling event, they are phenotypically linked; thus, mutations in gurken or Egfr typically affect eggshell and embryonic structures equally (Clifford and Schüpbach, 1989; Nilson and Schüpbach, 1999
; Schüpbach, 1987
). Eggs laid by females transheterozygous for strong hypomorphic mutations in Ras exhibit eggshell defects similar to those laid by gurken or Egfr mutants, implicating Ras in dorsoventral patterning of the follicle cells (Schnorr and Berg, 1996
). Surprisingly, however, these Ras hypomorphic mutations do not compromise embryonic dorsoventral patterning: Ras eggshells are ventralized but produce embryos with no detectable dorsoventral defects. This same differential phenotype is also seen with loss-of-function mutations affecting two other members of the Drosophila Ras signaling cassette, Raf and MEK (Brand and Perrimon, 1994
; Hsu and Perrimon, 1994
).
Two hypotheses can explain this discrepancy between eggshell and embryonic phenotypes resulting from Ras mutations. First, both eggshell and embryonic patterning absolutely require Ras, but eggshell patterning is more sensitive than embryonic patterning to reductions in Ras. Indeed, both Ras and mek mutations can suppress the dorsalized embryo phenotype resulting from mislocalization of grk mRNA in K10 mutant females, revealing a role in embryonic patterning (Hsu and Perrimon, 1994; Schnorr and Berg, 1996
). This hypothesis predicts that Ras null follicle cells would fail to repress pipe, leading to severe defects during embryonic dorsoventral patterning. Alternatively, an effector pathway other than the Ras signaling cassette relays Egfr activity to the nucleus to initiate dorsoventral patterning of the embryo. The EGF receptor can signal through Ras-independent effectors in mammalian cells, such as Src kinases, phospholipase C
and phosphatidylinositol 3-kinase (for a review, see Schlessinger, 2000
), all of which have Drosophila homologs (Lu and Li, 1999
; MacDougall et al., 1995
; Shortridge and McKay, 1995
). This hypothesis predicts that Rasnull follicle cells would exhibit normal dorsal pipe repression, resulting in mild, if any, dorsoventral patterning defects in the embryo.
Here, we test these hypotheses by generating Ras null follicle cell clones. These mosaic analyses reveal that Ras is required to repress pipe transcription, the critical first step in embryonic dorsoventral patterning. However, additional embryonic patterning events downstream of pipe can compensate for loss of Ras function in dorsal follicle cell clones, demonstrating that embryonic dorsoventral patterning is a self-regulating, robust process. Furthermore, dorsal Ras clones do not affect lateral repression of pipe, adding support to the hypothesis that low levels of Gurken repress pipe laterally rather than a secondary signal emanating from dorsal follicle cells. Additionally, we characterize the requirement for Ras in dorsal appendage morphogenesis. Confocal analyses of mosaic follicular epithelia reveal that Ras is required at the onset of dorsal follicle cell morphogenesis and for a novel basal localization pattern of the adhesion protein E-cadherin on the dorsal midline. We propose a hypothesis for dorsoventral patterning that explains the disparity between the eggshell and embryonic patterning phenotypes of Ras hypomorphic mutants and we address why those phenotypes are not shared by Egfr mutants. Finally, we discuss the potential roles for, and possible effectors of, Ras signaling in the morphogenesis of dorsal follicle cells.
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MATERIALS AND METHODS |
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To ensure that the defects we detected were due to loss of Ras function and not a background mutation, we compared the eggshell phenotypes of two independent FRT82B RasC40b chromosomes and found them to be identical (data not shown). To analyze wild-type pipe-lacZ expression, we dissected females of genotype w; pipe-lacZ. For all remaining experiments, we used Ras mosaic females of genotype hsFLP/+; pipe-lacZ/+; FRT82B Ras
C40b/FRT82B hsNmyc. As a negative control, we used females genetically identical to the Ras mosaic females except that they bore a wild-type FRT82B chromosome instead of the FRT Ras
C40b chromosome. We refer to clones in egg chambers from these flies as control clones. To ensure that the absence of the myc epitope in mosaic egg chambers was due to the presence of a clone rather than a mechanical insult to the epithelium, we co-stained egg chambers with DAPI (4',6-diamidino-2-phenylindole) to detect the presence of nuclei and, hence, intact follicle cells (data not shown).
To generate clones homozygous for the null allele EgfrCO (Clifford and Schüpbach, 1989), we employed the same protocol as above, except the females were of genotype hsFLP/+; FRT42D EgfrCO/FRT42D hs
myc; +/TM6, pipe-lacZ. The TM6, pipe-lacZ strain was constructed by mobilizing a second-chromosome P[w+; pipe-lacZ] element using
2-3 transposase and standard genetic crosses.
Frequency and size of marked follicle cell clones
By dissecting ovaries at multiple time-points after FLP induction, we found that 6 days was optimal to generate relatively large Ras clones of 57 cells, on average (n=30), in stage 9-12 egg chambers. This time-frame also produced the highest possible frequency of Ras clones and associated eggshell defects, with 20% of stage 9-12 (n=146) egg chambers containing a clone and 16% of stage 14 eggshells bearing dorsal appendage defects (n=158). By comparison, control clones were composed of 106 cells, on average, in stage 9-12 egg chambers at 6 days post-induction (n=39), and 24% of control egg chambers contained a clone (n=169), roughly consistent with previously reported results for wild-type clones (Margolis and Spradling, 1995). Only 1% of stage 14 control clone eggshells bore dorsal appendage defects (n=115).
The reduced average size and frequency of Ras clones compared to control clones indicates a cell division or survival deficit of the RasC40b cells. Furthermore, by dissecting females 10 days after induction, we attempted to identify large clones derived from follicle cell stem cells homozygous for Ras
C40b. We were unable to recover such clones, suggesting a requirement for Ras in follicle cell stem cell division or survival, or, alternatively, in the continued survival of clones growing from Ras
C40b stem cells.
While Ras clones were recovered at a relatively high frequency 5-7 days post-induction, EgfrCO clones were virtually nonexistent at those time points: at 5 days post-induction, only 2% of egg chambers bore EgfrCO clones (n=176) of an average size of 5 cells (n=4). By contrast, 60% of control egg chambers bore clones (n=85) of average size of 275 cells (n=18). By decreasing post-induction time to 3 days, we improved the frequency of EgfrCO clones to 30% (n=146), with an average clone size of 10 follicle cells (n=67). At this same time point, 88% of control egg chambers had clones of average size 16 cells (n=103). Since EgfrCO clones were smaller and less frequent than RasC40b clones, we hypothesize that Egfr perdures for a shorter time or plays a different role than Ras in follicle cell division and/or survival.
Immunofluorescence and microscopy
Ovaries were fixed and stained according to the method of Jackson and Berg (Jackson and Berg, 1999), except that 0.2 µg/ml DAPI was added during the third post-secondary wash. The following antisera were used: rabbit anti-ß-galactosidase (Cappel, 1:1000), mouse monoclonal anti-c-myc (Oncogene, 1:50), rat monoclonal anti-Drosophila-E-cadherin D-CAD2 (1:50) (Oda et al., 1994
). Primary antibodies were detected using standard dilutions (1:100-1:500) of fluorescently labeled secondary antibodies from Molecular Probes except for the rabbit ß-galactosidase antibody, which was detected using anti-rabbit-Texas Red (Cappel, 1:1000).
For anti-Twist immunofluorescence with embryos, we employed a standard antibody protocol (Protocol 95) (Ashburner, 1989) with the following modifications. Embryos were dechorionated in 50% bleach, fixed in PBS/50% heptane/2% paraformaldehyde, and, after devitellinization, stored in methanol at 4°C. Peroxide treatment was skipped, washes were done in PBT (PBS + 0.2% Tween 20), and blocking and antibody incubations were done in PBT/5% BSA/0.02% sodium azide. Embryos were incubated in 1:5000 anti-Twist primary antibody (Roth et al., 1989
), rinsed in PBT, incubated in 1:2000 biotinylated anti-rabbit antibody, rinsed again, then incubated in 1:100 streptavidin-FITC conjugate.
Labeled ovaries and embryos were examined using a Biorad MRC600 confocal microscope. A Nikon Microphot-FXA was used for rapid scoring of mosaic egg chambers, detection of DAPI, and DIC microscopy. Images were analyzed and processed using NIH Image and Adobe Photoshop.
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RESULTS |
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First, to ensure the accuracy of our analyses, we characterized how pipe-lacZ expression is spatially refined over time in wild-type egg chambers (Fig. 1) and then compared that pipe-lacZ pattern to the published pipe mRNA expression pattern (Sen et al., 1998) (F. Peri, M. Technau and S. Roth, personal communication). Beginning at stage 7 and until stage 10B, pipe-lacZ was expressed in posterior follicle cells and, as posterior follicle cell migration proceeded, in the nascent stretch follicle cells. Prior to stage 9 of oogenesis, pipe-lacZ was also expressed in a sagittal ring of follicle cells at the anterior margin of the growing columnar epithelium (Fig. 1A, bracket), and by stage 10B, only the ventral cells of the ring retained expression, constituting the anterior part of the well-defined stage 10 pipe pattern (Fig. 1D). Importantly, at the anterior of the columnar epithelium, pipe-lacZ expression protruded dorsally from the ventral domain in many stage 10A and early 10B egg chambers (Fig. 1C, arrowhead). This protrusion is the last remnant of dorsal sagittal ring expression before it finally resolves into the ventral zone of expression. This observed pipe-lacZ expression is consistent with the reported pattern of endogenous pipe mRNA (Sen et al., 1998
) (F. Peri, M. Technau and S. Roth, personal communication).
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Dorsal Ras clones do not affect lateral repression of pipe
To address whether lateral repression of pipe depends directly on Gurken or on a secondary signal emanating from the dorsal anterior follicle cells, we asked whether lateral pipe-lacZ repression was altered by the presence of dorsal Ras clones. We reasoned that if the secondary signaling hypothesis is correct, dorsal patches lacking Ras would not only lose repression of pipe in a cell-autonomous fashion, but would also fail to secrete secondary signaling molecules to repress pipe at a distance. In contrast, if lateral repression of pipe results from direct contact with low levels of Gurken at lateral positions in the oocyte, dorsal Ras clones should not compromise lateral repression of pipe.
In five of eight lateral views of egg chambers with dorsal Ras clones, lateral repression of pipe-lacZ appeared normal (Fig. 2D). Three of eight egg chambers, however, exhibited a mild dorsal expansion of the ventral pipe-lacZ expression domain (Fig. 2E), but these expansions did not differ significantly from those characteristic of the dynamic wild-type pipe-lacZ expression pattern (Fig. 1B,C). Therefore, the presence of dorsal Ras follicle cell clones did not strongly affect lateral repression of pipe-lacZ, supporting the hypothesis that Gurken directly represses pipe in lateral follicle cells. Consistent with these data, Peri and colleagues (F. Peri, M. Technau and S. Roth, personal communication) report similar results from examination of pipe-lacZ in marked loss-of-function Raf clones. Although Raf clones cause cell-autonomous de-repression of pipe-lacZ, dorsal Raf clones do not disrupt lateral pipe-lacZ repression. Furthermore, they show that clones expressing a constitutively activated form of the EGF receptor do not disrupt pipe-lacZ expression in surrounding cells.
Our observations notwithstanding, it is still possible that the wild-type unevenness of the lateral edge of pipe-lacZ expression may have masked a subtle expansion in pipe-lacZ caused by dorsal Ras clones. Therefore, we conclude that if dorsal Ras clones relieve lateral pipe-lacZ repression, the effect is very small. Our result is consistent with the hypothesis proposed by Pai et al. (Pai et al., 2000), in which Gurken directly defines the pipe repression domain.
Dorsoventral patterning events downstream of pipe can compensate for loss of Ras function in dorsal follicle cell clones
Mosaic analyses demonstrate that loss of pipe in ventral follicle cells leads to local embryonic dorsalization (Nilson and Schüpbach, 1998). Furthermore, pipe expression is sufficient to induce ventral embryonic cell fate since ectopic expression of pipe throughout the follicular epithelium causes embryonic ventralization (Sen et al., 1998
). These results point to a spatial relationship between pipe in the egg chamber and ventral cell fate in the embryo. Therefore, we predicted that the ectopic expression of pipe observed in Ras follicle cell clones should translate into local embryonic patterning defects.
Dorsoventral patterning of the embryo can be directly visualized in cellularizing embryos by detecting asymmetrically expressed molecular markers. High levels of nuclear Dorsal induce the expression of Twist protein in a ventral stripe occupying approximately 20% of the embryonic circumference, which invaginates at the onset of gastrulation to form the ventral furrow (Thisse et al., 1988). Mutations in gurken and Egfr ventralize the eggshell and embryo, expanding embryonic Twist protein dorsally (Roth and Schüpbach, 1994
).
To test whether the ectopic expression of pipe observed in Ras follicle cell clones translates directly into ectopic Twist in the embryo, we examined Twist protein in cellularizing embryos derived from egg chambers bearing dorsal Ras clones. The study of embryonic phenotypes resulting from follicle cell clones is difficult because the follicular epithelium is sloughed off before embryonic development begins. Therefore, we took advantage of the fact that eggs laid by Ras mosaic females displayed dorsal appendage defects associated with dorsal anterior Ras clones (Figs 4, 5). By selecting eggs with appendage defects indicative of dorsal anterior clones (Fig. 4E, asterisks), we ensured analysis of Twist protein specifically in embryos resulting from egg chambers with dorsal Ras clones. We avoided ventralized eggs (see drawing in Fig. 4E) because that phenotype may also result from posterior Ras clones that prevent anterior-posterior patterning, a prerequisite for dorsoventral patterning. We predicted that, if ectopic pipe in the egg chamber is sufficient to induce ectopic Twist in the embryo on a cell-by-cell basis, 100% of eggs with appendage defects should display ectopic Twist expression in the dorsal anterior region of the cellularizing embryo.
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Ras mutant cells fail to participate in dorsal follicle cell migration
Dorsoventral patterning within the follicular epithelium precedes the anterior migration of two dorsolateral populations of follicle cells, or dorsal appendage primordia, which ultimately secrete the dorsal respiratory appendages of the eggshell. Mutants carrying strong Ras loss-of-function mutations lay eggs with fused dorsal appendages, demonstrating the requirement for Ras during patterning of the dorsal appendage primordia (Schnorr and Berg, 1996). Our mosaic analyses allowed us to ask whether Ras is also required for dorsal appendage morphogenesis and to examine the behavior of wild-type and mutant cells in mosaic egg chambers.
First, we evaluated the phenotype of eggs laid by Ras mosaic females 5-7 days after clone induction. 16% of stage 14 eggshells displayed some type of dorsal appendage defect (n=158). Defects ranged from the complete ablation of dorsal appendages in the most severe case, to a small nub of extra chorion material adjacent to two normal dorsal appendages in the least severe case (Fig. 4). Ablation or, rarely, fusion of the dorsal appendages occurred only in a small fraction of defective eggs and likely resulted from either a very large dorsal anterior clone or a posterior clone that prevented posterior cell fate establishment and, therefore, hindered anterior migration of the oocyte nucleus, a prerequisite for dorsal Gurken signaling. The most common phenotype was a small nub of chorion material in place of a normal dorsal appendage (Fig. 4B,D, Fig. 5A). Some defective eggs had two nubs in place of dorsal appendages (Fig. 4C); others bore shortened or fragmented dorsal appendages (Fig. 4E).
To determine whether aberrant nubs or fragments of dorsal appendages were formed by the Ras mutant cells or by wild-type (Ras/+ or +/+) cells adjacent to Ras clones, we dissected ovaries and analyzed stage 14 mosaic egg chambers with chorion defects (Fig. 5A-D). At this late stage, the follicular epithelium is rapidly degrading, but some stage 14 egg chambers can be found in which the follicular epithelium remains intact. In all nine of these egg chambers, extra chorion nubs or fragments of dorsal appendages were secreted by wild-type cells, and in all cases, these wild-type cells abutted Ras clones (Fig. 5B,D). Thus, Ras mutant cells did not migrate or secrete the appendage material forming the aberrant chorion structures, but rather, impinged on the activities of nearby wild-type cells, either by obstructing their movement or by reducing the number of cells fated to migrate. Interestingly, in one egg chamber, a nub of chorion material was surrounded by only about eight follicle cells, indicating that a relatively small number of wild-type cells can organize and secrete a dorsal appendage nub (Fig. 5B,C).
Some aberrant appendage structures had a characteristic teardrop shape (Fig. 4D). These appendages form when wild-type cells at the posterior of a dorsal appendage primordium encounter a Ras clone in a more anterior position (Fig. 5D) and are unable to migrate between or over them. We speculate that the cells of the Ras clone adhere strongly to the substratum (basal lamina or stretch cells) and to each other, thereby blocking the anterior migration of the wild-type cells.
Finally, we searched stage 13 and 14 mosaic egg chambers for any mutant cells that might have been included, actively or passively, in the group of follicle cells extending anteriorly to make the dorsal appendages. In control mosaic egg chambers, clones were often found amongst the migrating population (Fig. 5E). In over 400 Ras mosaic egg chambers, however, we never detected mutant cells in the migrating group. Therefore, Ras mutant cells were neither found amongst the migrating cohort of dorsolateral follicle cells nor responsible for secreting aberrant chorion structures. Thus, Ras mutant cells failed to participate, actively or passively, in dorsal follicle cell migration or secretion of dorsal appendage chorion.
Ras mutant cells do not undergo cell shape changes characteristic of dorsal follicle cell morphogenesis
Analysis of late-stage mosaic egg chambers reveals the final outcome of dorsal follicle cell movements but does not show how wild-type and mutant cells behave throughout the morphogenetic process itself. We therefore investigated whether Ras mosaic egg chambers exhibit defects during the earliest events of dorsal appendage morphogenesis and how wild-type (Ras/+ or +/+) cells respond to neighbors lacking Ras function.
The two dorsolateral appendage primordia begin morphogenesis by undergoing a characteristic cell shape change in which apical diameter decreases relative to that of the cells outside the primordia (J. D., K. J., D. Kiehart and C. B., unpublished data). To test whether Ras mutant cells within the dorsal appendage primordia undergo this shape change, we carried out confocal analyses of mosaic egg chambers in which we simultaneously detected Ras clones and visualized cell morphology using one of two reagents: rhodamine-phalloidin, which binds to filamentous actin, or anti-E-cadherin, which highlights apical morphology (Fig. 6A). Apical morphology of the dorsal appendage primordia was grossly disrupted in all egg chambers with dorsal anterior Ras clones (n=14). This disruption was particularly clear in one egg chamber in which a Ras clone covering an anterior region of the left appendage primordium displayed a marked increase in apical diameter (Fig. 6B-E). The apical diameters of the surrounding wild-type (Ras/+) cells in the primordium were appropriately small. We hypothesize that this egg chamber, if allowed to develop, would have produced a fragmented dorsal appendage phenotype (see drawing in Fig. 4E) because the wild-type migrating cohort was split into two groups.
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Ras is required for the basal localization of E-cadherin on the dorsal midline
Since Ras mutant follicle cells did not participate, not even passively, in dorsal follicle cell migration, and since these cells sometimes appear to obstruct the migration of wild-type follicle cells by adhering strongly to the substratum and preventing the anterior migration of the wild-type cells (Fig. 5D), we reasoned that Ras mutant cells may not properly regulate the expression or localization of adhesion molecules. Developmentally regulated adhesion mediated by Drosophila E-cadherin (E-Cad) orchestrates specific morphogenetic movements and maintains the integrity of epithelia undergoing mechanical stress (for a review, see Tepass, 1999). Previous studies showed that precise regulation of E-Cad in follicle cells is required for oocyte positioning, centripetal migration and border cell migration (Godt and Tepass, 1998
; Niewiadomska et al., 1999
). Furthermore, EGF receptor activity has been linked with the regulation of E-cadherin expression and invasiveness in human cancer cell lines (Alper et al., 2000
; Jones et al., 1996
). We therefore examined E-Cad protein by confocal microscopy of Ras mosaic egg chambers.
We first analyzed E-cadherin protein localization in control egg chambers; as previously reported, E-Cad was localized in the follicular epithelium in a honeycomb pattern corresponding to the zonula adherens (Niewiadomska et al., 1999). Surprisingly, in addition to this apicolaterally localized E-Cad, egg chambers undergoing dorsal appendage morphogenesis also exhibited basal localization of E-Cad in an anterior swath of dorsal midline cells and in a ring of anterior columnar follicle cells (Fig. 7A) (J. D., K. J., D. Kiehart and C. B., unpublished data).
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DISCUSSION |
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Our data are consistent with the hypothesis that additional patterning events modify the initial asymmetry determined by Egfr signaling and thereby establish the final Dorsal gradient. Additional patterning downstream of Egfr has also been suggested to explain another observation, that the embryonic phenotype resulting from maternal mutations in gurken or Egfr is not simply an expansion of ventral embryonic fates, as detected by Twist expression and formation of a larger ventral furrow. Rather, many embryos exhibit a pattern duplication characterized by two ventrolateral regions of maximum nuclear Dorsal and Twist, separated by a ventral minimum, which leads to the eventual invagination of two furrows (Roth and Schüpbach, 1994; Schüpbach, 1987
). Our result that Ras clones cell-autonomously derepress pipe suggests that such a refinement process occurs downstream of pipe.
Consistent with our findings, Morisato (Morisato, 2001) demonstrated that the additional patterning events that govern the shape of the Dorsal gradient in wild-type embryos (and can create two furrows in ventralizing mutants) do not occur in the follicular epithelium. Rather, the refinement process occurs at the level of Spätzle processing or Toll activation in the embryo. Furthermore, elegant mosaic analyses carried out by Nilson and Schüpbach (Nilson and Schüpbach, 1998
) reveal that, while loss-of-function pipe or windbeutel (wind) clones on the ventral side of the egg chamber result in a local loss of ventral Twist expression in the embryo, ventral clones of pipe or wind also exert a non-autonomous effect on lateral embryonic fates. These investigators hypothesize that an 8-12 cell wide ventral region in the egg chamber (defined by the spatial requirement for pipe) generates ventral information, perhaps imbedded in the vitelline membrane, which is then competent to establish the Dorsal gradient along the entire dorsoventral axis, presumably via outward diffusion of a ventral morphogen.
In addition, other patterning mechanisms that influence the Dorsal gradient have been discovered recently. Nuclear translocation of Dorsal can be modified by maternal Sog and Dpp in a pathway parallel to Toll signaling (Araujo and Bier, 2000). Also, the serine protease cascade upstream of Toll is subject to feedback inhibition, providing an additional level of regulation (Dissing et al., 2001
; Han et al., 2000
).
Our work, together with the discoveries discussed above, points to a model (Fig. 8B, top) in which the initial asymmetry generated by restriction of pipe to the ventral-most 40% of the egg chamber leads to the cleavage of the zymogen Spz in the ventral-most 40% of the perivitelline space. The positive ventralizing activity of C-Spz is opposed by the activity of a diffusible inhibitor, possibly N-Spz (Morisato, 2001). In wild-type patterning, this inhibitor narrows the domain of ventralizing C-Spz activity, originally determined by pipe expression in follicle cells, from 40% of the perivitelline space to approximately 20%. This narrower region of ventralizing activity then activates Toll in a graded fashion, defining the final shape of the Dorsal gradient.
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Support for this hypothesis comes from the analysis of egg chambers with ventral wind clones surrounding small islands of wild-type cells in ventral-most positions (Nilson and Schüpbach, 1998). In these instances, if the wild-type island is less than 4-6 cells wide, it is not able to induce Twist expression in the embryo. This situation is similar to our result that dorsal Ras clones fail to induce Twist. Together, our data suggest that ventral information from small patches of cells expressing pipe can be swamped out by neighboring dorsally-fated cells, probably through the function of a diffusible inhibitor.
Embryonic dorsoventral patterning is robust
The ventralizing activity of ectopic pipe expression in Ras mosaic egg chambers can be overcome by post-pipe patterning events. The existence of this compensatory mechanism demonstrates that embryonic dorsoventral patterning is a robust process. This resilience is generated by the action of additional rounds of pattern refinement, which may help to buffer these important early events of embryonic development from perturbations in signaling caused by genetic defects or environmental factors. Furthermore, the zygotic genes that orchestrate dorsoventral patterning (Dpp/BMP4 and Sog/chordin) are conserved between arthropods and chordates, and, extraordinarily, their biological function in dorsoventral patterning is also conserved (for a review, see Ferguson, 1996). However, where flies use post-pipe pattern refinement to buffer the Dorsal gradient, which determines the Dpp/Sog pattern, chordates use a completely different developmental pathway to arrive at the BMP4/chordin patterning event. Consequently, the specific mechanism of dorsoventral buffering in flies cannot be shared by chordates, suggesting that each group evolved unique mechanisms to buffer the conserved aspects of dorsoventral patterning. Understanding the degree of diversity among buffering systems will be useful in determining evolutionary relationships and will facilitate studies examining the evolution of developmental mechanisms.
Eggshell versus embryo
To explain the differential phenotype of eggs laid by females transheterozygous for strong hypomorphic alleles of Ras, we hypothesized that either eggshell patterning is more sensitive than embryonic patterning to reductions in Ras, or a Ras-independent Egfr effector pathway mediates embryonic patterning. The cell-autonomous derepression of pipe in Ras null clones demonstrates that Ras is required to initiate embryonic dorsoventral patterning and suggests that the first hypothesis is correct. Conversely, the result that embryos developing from Ras mosaic egg chambers are rarely abnormal supports the second hypothesis, with the added complexity that the Ras-independent effector pathway must also bypass pipe. As described above, however, our data suggest that very large Ras clones, or an entirely mutant epithelium, would induce ectopic Twist expression in the embryo and lead to severe embryonic dorsoventral patterning defects.
Indeed, in five of 26 cases, Ras follicle cell clones did result in ectopic Twist in the embryo, presumably because those clones were large enough to overcome the post-pipe patterning events that dampen the ventralizing effects of smaller clones. Furthermore, ectopic expression of pipe throughout the follicular epithelium is indeed sufficient to cause embryonic ventralization (Sen et al., 1998). Therefore, the lack of embryonic defects resulting from most Ras mutant follicle cell clones, which are too small to overcome post-pipe patterning processes, is misleading with respect to the question of whether Ras is required generally for embryonic dorsoventral patterning. Given these considerations, our results are more consistent with the first hypothesis, that is, Ras is required for dorsoventral patterning of the embryo, and eggshell patterning is more sensitive than embryonic patterning to reductions in Ras.
Despite the appeal of this conclusion, the formal possibility remains that an Egfr-dependent, Ras-independent dorsalizing factor feeds into the embryonic patterning pathway downstream of pipe. Such a hypothesis, however, requires complex rationalizations. For example, it conflicts with elegant experiments conducted by Sen and colleagues (Sen et al., 1998) in which ectopic dorsal expression of pipe in pipe mutant egg chambers causes reversal of embryonic dorsoventral polarity. If an Egfr-dependent, Ras-independent, post-pipe dorsalizing factor existed, one would predict that ectopic dorsal expression of pipe in a pipe mutant egg chamber would exert little to no effect on the pipe mutant phenotype. Furthermore, numerous screens for dorsoventral patterning mutants have failed to recover components of known Ras-independent Egfr effector pathways. Thus, we favor the hypothesis that Ras is required to establish embryonic dorsoventral polarity.
Eggshell sensitivity and Ras specificity
Why would eggshell patterning be more sensitive than embryonic patterning? Furthermore, why would that sensitivity be specific to reductions in Ras and not Gurken or Egfr? Two hypotheses can explain why eggshell patterning would be acutely sensitive specifically to reductions in Ras. First, dorsoventral patterning of the eggshell requires amplification and modulation of Egfr activity, achieved by autocrine signaling involving Spitz, Rhomboid, Vein, and Argos, to define two dorsolateral populations of follicle cells. These post-Gurken patterning events are eggshell-specific, while pipe repression is achieved solely by Gurken signaling (for a review, see Van Buskirk and Schüpbach, 1999). Furthermore, since our results support the hypothesis that low lateral levels of Gurken suffice to repress pipe (Pai et al., 2000
), it is likely that pipe repression requires only low-level signaling. The hypomorphic Ras mutations primarily affect the transcription of Ras (Schnorr and Berg, 1996
), which, theoretically, reduces the number of Ras molecules rather than the effectiveness of each molecule. Therefore, the hypomorphic mutant may produce enough Ras molecules to transduce the initial Gurken signal, repress pipe and pattern the embryo, but too few Ras molecules to transduce the high levels of Egfr signaling required for eggshell patterning. Thus, the number of Ras molecules may be limiting for eggshell patterning, which requires an intense surge of Ras signaling, but not limiting for pipe repression, which may be accomplished with only a trickle of signaling that is easily transduced by a small number of Ras molecules.
This amplification threshold hypothesis predicts that, like Ras, Egfr mutations would cause a differential phenotype since Egfr is also involved in eggshell-specific signal amplification. Egfr mutations, however, affect eggshell and embryonic patterning equally. The nature of the Egfr and Ras alleles used in the analysis of dorsoventral phenotypes may provide an explanation. The Ras hypomorphic mutations analyzed by Schnorr and Berg (Schnorr and Berg, 1996) are lethal EMS mutations in trans to a P-element insertion that simply reduces the level of the wild-type Ras transcript. By contrast, viable Egfr alleles such as top1, topCJ, and topEE38 specifically affect the ligand-binding domain of the receptor (Clifford and Schüpbach, 1994
). In addition, these alleles were isolated in mutagenesis screens that demanded viability (Schüpbach, 1987
). Therefore, since the Egfr ligands Spitz and Vein are required throughout embryonic and larval development whereas Gurken is required only in oogenesis, the Egfr alleles isolated in such a screen are likely to disproportionately affect Gurken signaling. Since Gurken initiates both eggshell and embryonic patterning, while the other ligands bring about eggshell-specific Egfr signal amplification, these unique Egfr alleles would be expected to compromise eggshell and embryonic patterning equally. We speculate that a genuine hypomorphic mutation affecting the overall levels of Egfr protein would behave like the hypomorphic P allele of Ras (strong eggshell defects, weak dorsoventral embryonic defects). Indeed, Clifford and Schüpbach (Clifford and Schüpbach, 1989
) observed that some Egfr mutant females lay rare eggs with fused dorsal appendages that give rise to normal embryos.
A second hypothesis can also explain why eggshell patterning would be more sensitive than embryonic patterning specifically to reductions in Ras. Our data demonstrate that Ras mutant cells fail to initiate or accomplish dorsal follicle cell morphogenesis. These phenotypes, along with our pipe-lacZ results, suggest that Ras is required to establish dorsal follicle cell fate, a prerequisite for morphogenesis. Our data are also consistent with an additional requirement for Ras specifically regulating morphogenesis. Gurken and Egfr, however, may be directly required only for patterning and may therefore influence morphogenesis only indirectly. In support of this hypothesis, the Nrk receptor tyrosine kinase, identified as an Enhancer of Ras in eggshell development, may provide an independent Ras pathway input specific for morphogenesis (Schnorr et al., 2001). Thus, a Ras mutation that produces weak embryonic defects may dramatically disrupt eggshell structures by affecting both patterning and morphogenesis. This synergism may compromise dorsal appendage morphology enough to resemble the eggshell phenotype of a severe gurken or Egfr allele, which affects eggshell and embryo equally (Schnorr and Berg, 1996
; Schüpbach, 1987
).
Ras and cell migration: patterning versus morphogenesis
In addition to extending our understanding of embryonic dorsoventral patterning and defining the relative contribution of Ras signaling toward establishing eggshell and embryonic fates, our mosaic analyses have revealed the requirement for Ras during dorsal appendage morphogenesis. How might Ras regulate dorsal follicle cell migration (Fig. 8A)? By transducing signals for dorsal follicle cell fate, Ras may affect transcription of genes involved in morphogenesis. Notably, Broad-Complex (BR-C), Mirror, Bunched, and Fos/Kayak respond to Egfr signaling and likely affect transcription of genes involved in dorsal appendage formation (Deng and Bownes, 1997; Dequier et al., 2001
; Dobens et al., 1997
; Jordan et al., 2000
). Alternatively, Ras activity may directly affect key cytoskeletal or adhesion molecules that play active roles during the morphogenetic process. Since many of the events of dorsal follicle cell morphogenesis occur quite rapidly stage 11, for example, encompasses profound morphogenetic changes (J. D., K. J., D. Kiehart and C. B., unpublished data), but is completed in less than 30 minutes (Lin and Spradling, 1993
), and since MAP kinase activity is dynamic during the early stages of morphogenesis (Peri et al., 1999
), we suspect that Ras signaling directly modulates the activity of migration molecules. Most likely, Ras functions in dorsal follicle cell migration through some combination of direct cytoplasmic effects and transcriptional regulation.
To understand the role of Ras in cell migration, we can look to other migration events controlled by Ras signaling. In Drosophila, disruptions in Ras signaling can hinder the migration of a subset of follicle cells called border cells (Duchek and Rørth, 2001; Lee et al., 1996
). Significantly, border cell fate remains properly specified in these experiments, revealing migration-specific functions for Ras. Importantly, the movement of dorsal follicle cells differs significantly from that of border cells, which navigate through germline cells as a small epithelial patch (Niewiadomska et al., 1999
). Dorsal appendage formation involves the coordinated morphogenetic movements of an epithelial sheet (J. D., K. J., D. Kiehart and C. B., unpublished data). These differences demonstrate that each migration event offers a unique opportunity to study the role of Ras during developmentally regulated cell migration in Drosophila.
Ras effectors in dorsal follicle cell morphogenesis: a novel role for E-cadherin?
What are the effectors of Ras during dorsal follicle cell migration? One possibility is E-cadherin, since Ras is required for the basal localization of this molecule in midline follicle cells. Importantly, the levels of apicolaterally-localized E-Cad appear normal in Ras clones. This result suggests that Ras signaling does not regulate the canonical adherens-junction function of E-Cad, which provides integrity to the epithelium during morphogenesis. Instead, Ras affects the basal localization of E-Cad on the dorsal midline, which may anchor the midline cells or otherwise influence the mechanical movements of the dorsal appendage primordia.
The loss of basal E-Cad in a Ras clone on the midline was surprising because the dorsal midline is thought to be a region of significantly diminished Egfr activity (Peri et al., 1999). Why, then, would Ras be required there for the localization of an adhesion molecule? Perhaps Ras signaling is actually active on the dorsal midline between stages 10B and 12. Alternatively, a history of high and then low Egfr/Ras signaling may be required for basal E-Cad protein localization in midline cells. Further exploration of the precise regulation of E-Cad during dorsal follicle cell morphogenesis is needed to elucidate the relationship between Ras signaling and E-Cad localization, and to address whether basal localization of E-Cad in anterior and midline cells is required for the proper morphogenesis of dorsal appendages.
In addition to E-Cad, Ras may regulate other adhesion, signaling, or cytoskeletal molecules to permit or instruct dorsal follicle cell migration. Known cellular effectors of Ras in mammalian cells include c-Raf, RalGDS, and PI 3 kinase (for a review, see Bar-Sagi and Hall, 2000). To identify molecules that interact with Ras in Drosophila follicle cells, Schnorr and colleagues (Schnorr et al., 2001
) screened for dominant enhancers of a weak Ras eggshell phenotype. They identified 13 strong enhancers that can be grouped into two major molecular categories: signaling and cytoskeleton. Interestingly, two enhancers, dock and Tec29A, encode signaling molecules that directly regulate cytoskeletal function (Garrity et al., 1996
; Guarnieri et al., 1998
; Rao and Zipursky, 1998
; Roulier et al., 1998
). Studies that separate cell fate specification from morphogenetic events are needed to determine whether Ras actively controls the morphogenesis of dorsal follicle cells.
In conclusion, our finding that Ras is required for pipe repression argues against the hypothesis that a Ras-independent pathway transduces Egfr signals to pattern the embryo. This result contributes to the growing body of evidence that, in Drosophila, Egfr signaling is transmitted to the nucleus primarily by the Ras pathway rather than by alternative effector molecules. Furthermore, our data demonstrate that dorsoventral patterning is buffered by post-pipe patterning events that define the final shape of the embryonic dorsoventral gradient. Additionally, we show that Ras is required for dorsal appendage patterning and morphogenesis as well as for the proper subcellular localization of E-cadherin, a major epithelial adhesion protein. Ras signaling is linked to cell migration in many developmental and disease contexts, providing justification for further dissection of Ras pathway function during dorsal appendage morphogenesis in Drosophila.
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ACKNOWLEDGMENTS |
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REFERENCES |
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Alper, O., De Santis, M. L., Stromberg, K., Hacker, N. F., Cho-Chung, Y. S. and Salomon, D. S. (2000). Anti-sense suppression of epidermal growth factor receptor expression alters cellular proliferation, cell-adhesion and tumorigenicity in ovarian cancer cells. Int. J. Cancer 88, 566-574.[Medline]
Anderson, K. (1998). Pinning down positional information: Dorsal-ventral polarity in the Drosophila embryo. Cell 95, 439-442.[Medline]
Araujo, H. and Bier, E. (2000). sog and dpp exert opposing maternal functions to modify toll signaling and pattern the dorsoventral axis of the Drosophila embryo. Development 127, 3631-3644.
Ashburner, M. (1989). Drosophila, A Laboratory Manual. pp. 214-215. Cold Spring Harbor, NY: Cold Spring Harbor Laboratory Press..
Bar-Sagi, D. and Hall, A. (2000). Ras and Rho GTPases: a family reunion. Cell 103, 227-238.[Medline]
Brand, A. H. and Perrimon, N. (1994). Raf acts downstream of the EGF receptor to determine dorsoventral polarity during Drosophila oogenesis. Genes Dev. 8, 629-639.[Abstract]
Campbell, S. L., Khosravi-Far, R., Rossman, K. L., Clark, G. J. and Der, C. J. (1998). Increasing complexity of Ras signaling. Oncogene 17, 1395-1413.[Medline]
Clifford, R. and Schüpbach, T. (1994). Molecular analysis of the Drosophila EGF receptor homolog reveals that several genetically defined classes of alleles cluster in subdomains of the receptor protein. Genetics 137, 531-550.
Clifford, R. J. and Schüpbach, T. (1989). Coordinately and differentially mutable activities of torpedo, the Drosophila melanogaster homolog of the vertebrate EGF receptor gene. Genetics 123, 771-787.
Deng, W. M. and Bownes, M. (1997). Two signalling pathways specify localised expression of the Broad-Complex in Drosophila eggshell patterning and morphogenesis. Development 124, 4639-4647.
Dequier, E., Souid, S., Pal, M., Maroy, P., Lepesant, J. A. and Yanicostas, C. (2001). Top-DER- and Dpp-dependent requirements for the Drosophila fos/kayak gene in follicular epithelium morphogenesis. Mech. Dev. 106, 47-60.[Medline]
Dissing, M., Giordano, H. and DeLotto, R. (2001). Autoproteolysis and feedback in a protease cascade directing Drosophila dorsal-ventral cell fate. EMBO J. 20, 2387-2393.
Dobens, L. L., Hsu, T., Twombly, V., Gelbart, W. M., Raftery, L. A. and Kafatos, F. C. (1997). The Drosophila bunched gene is a homologue of the growth factor stimulated mammalian TSC-22 sequence and is required during oogenesis. Mech. Dev. 65, 197-208.[Medline]
Duchek, P. and Rørth, P. (2001). Guidance of cell migration by EGF receptor signaling during Drosophila oogenesis. Science 291, 131-133.
Ferguson, E. (1996). Conservation of dorsal-ventral patterning in arthropods and chordates. Curr. Opin. Genet. Dev. 4, 424-431.
Garrity, P. A., Rao, Y., Salecker, I., McGlade, J., Pawson, T. and Zipursky, S. L. (1996). Drosophila photoreceptor axon guidance and targeting requires the dreadlocks SH2/SH3 adapter protein. Cell 85, 639-650.[Medline]
Ghiglione, C., Carraway, K. L., 3rd, Amundadottir, L. T., Boswell, R. E., Perrimon, N. and Duffy, J. B. (1999). The transmembrane molecule kekkon 1 acts in a feedback loop to negatively regulate the activity of the Drosophila EGF receptor during oogenesis. Cell 96, 847-856.[Medline]
Godt, D. and Tepass, U. (1998). Drosophila oocyte localization is mediated by differential cadherin-based adhesion. Nature 395, 387-391.[Medline]
Guarnieri, D. J., Dodson, G. S. and Simon, M. A. (1998). SRC64 regulates the localization of a Tec-family kinase required for Drosophila ring canal growth. Mol Cell 1, 831-840.[Medline]
Han, J., Zhang, H., Min, G., Kemler, D. and Hashimoto, C. (2000). A novel Drosophila serpin that inhibits serine proteases. FEBS Lett. 468, 194-198.[Medline]
Hou, X. S., Chou, T. B., Melnick, M. B. and Perrimon, N. (1995). The torso receptor tyrosine kinase can activate Raf in a Ras-independent pathway. Cell 81, 63-71.[Medline]
Hsu, J. C. and Perrimon, N. (1994). A temperature-sensitive MEK mutation demonstrates the conservation of the signaling pathways activated by receptor tyrosine kinases. Genes Dev. 8, 2176-2187.[Abstract]
Jackson, S. M. and Berg, C. A. (1999). Soma-to-germline interactions during Drosophila oogenesis are influenced by dose-sensitive interactions between cut and the genes cappuccino, ovarian tumor and agnostic. Genetics 153, 289-303.
Jones, J. L., Royall, J. E. and Walker, R. A. (1996). E-cadherin relates to EGFR expression and lymph node metastasis in primary breast carcinoma. Br. J. Cancer 74, 1237-1241.[Medline]
Jordan, K. C., Clegg, N. J., Blasi, J. A., Morimoto, A. M., Sen, J., Stein, D., McNeill, H., Deng, W. M., Tworoger, M. and Ruohola-Baker, H. (2000). The homeobox gene mirror links EGF signalling to embryonic dorso-ventral axis formation through notch activation. Nat. Genet. 24, 429-433.[Medline]
Lee, T., Feig, L. and Montell, D. J. (1996). Two distinct roles for Ras in a developmentally regulated cell migration. Development 122, 409-418.
Lin, H. and Spradling, A. C. (1993). Germline stem cell division and egg chamber development in transplanted Drosophila germaria. Dev. Biol. 159, 140-152.[Medline]
Lu, X. and Li, Y. (1999). Drosophila Src42A is a negative regulator of RTK signaling. Dev. Biol. 208, 233-243.[Medline]
MacDougall, L. K., Domin, J. and Waterfield, M. D. (1995). A family of phosphoinositide 3-kinases in Drosophila identifies a new mediator of signal transduction. Curr. Biol. 5, 1404-1415.[Medline]
Margolis, J. and Spradling, A. (1995). Identification and behavior of epithelial stem cells in the Drosophila ovary. Development 121, 3797-3807.
Morisato, D. (2001). Spatzle regulates the shape of the Dorsal gradient in the Drosophila embryo. Development 128, 2309-2319.
Niewiadomska, P., Godt, D. and Tepass, U. (1999). DE-Cadherin is required for intercellular motility during Drosophila oogenesis. J. Cell Biol. 144, 533-547.
Nilson, L. A. and Schüpbach, T. (1998). Localized requirements for windbeutel and pipe reveal a dorsoventral prepattern within the follicular epithelium of the Drosophila ovary. Cell 93, 253-262.[Medline]
Nilson, L. A. and Schüpbach, T. (1999). EGF receptor signaling in Drosophila oogenesis. Curr. Top. Dev. Biol. 44, 203-243.[Medline]
Oda, H., Uemura, T., Harada, Y., Iwai, Y. and Takeichi, M. (1994). A Drosophila homolog of cadherin associated with armadillo and essential for embryonic cell-cell adhesion. Dev. Biol. 165, 716-726.[Medline]
Pai, L. M., Barcelo, G. and Schüpbach, T. (2000). D-cbl, a negative regulator of the Egfr pathway, is required for dorsoventral patterning in Drosophila oogenesis. Cell 103, 51-61.[Medline]
Peri, F., Bokel, C. and Roth, S. (1999). Local Gurken signaling and dynamic MAPK activation during Drosophila oogenesis. Mech. Dev. 81, 75-88.[Medline]
Peri, F. and Roth, S. (2000). Combined activities of Gurken and decapentaplegic specify dorsal chorion structures of the Drosophila egg. Development 127, 841-850.
Rao, Y. and Zipursky, S. L. (1998). Domain requirements for the Dock adapter protein in growth-cone signaling. Proc. Natl. Acad. Sci. USA 95, 2077-2082.
Reich, A., Sapir, A. and Shilo, B. (1999). Sprouty is a general inhibitor of receptor tyrosine kinase signaling. Development 126, 4139-4147.
Roth, S. and Schüpbach, T. (1994). The relationship between ovarian and embryonic dorsoventral patterning in Drosophila. Development 120, 2245-2257.
Roth, S., Jordan, P. and Karess, R. (1999). Binuclear Drosophila oocytes: consequences and implications for dorsal-ventral patterning in oogenesis and embryogenesis. Development 126, 927-934.
Roth, S., Stein, D. and Nusslein-Volhard, C. (1989). A gradient of nuclear localization of the dorsal protein determines dorsoventral pattern in the Drosophila embryo. Cell 59, 1189-1202.[Medline]
Roulier, E. M., Panzer, S. and Beckendorf, S. K. (1998). The Tec29 tyrosine kinase is required during Drosophila embryogenesis and interacts with Src64 in ring canal development. Mol. Cell 1, 819-829.[Medline]
Ruohola-Baker, H., Grell, E., Chou, T. B., Baker, D., Jan, L. Y. and Jan, Y. N. (1993). Spatially localized rhomboid is required for establishment of the dorsal-ventral axis in Drosophila oogenesis. Cell 73, 953-965.[Medline]
Rusch, J. and Levine, M. (1996). Threshold responses to the dorsal regulatory gradient and the subdivision of primary tissue territories in the Drosophila embryo. Curr. Opin. Genet. Dev. 6, 416-423.[Medline]
Schlessinger, J. (2000). Cell signaling by receptor tyrosine kinases. Cell 103, 211-225.[Medline]
Schnorr, J. D. and Berg, C. A. (1996). Differential activity of Ras1 during patterning of the Drosophila dorsoventral axis. Genetics 144, 1545-1557.
Schnorr, J. D., Holdcraft, R., Chevalier, B. and Berg, C. A. (2001). Ras1 interacts with multiple new signaling and cytoskeletal loci in drosophila eggshell patterning and morphogenesis. Genetics 159, 609-622.
Schüpbach, T. (1987). Germ line and soma cooperate during oogenesis to establish the dorsoventral pattern of egg shell and embryo in Drosophila melanogaster. Cell 49, 699-707.[Medline]
Schweitzer, R. and Shilo, B. Z. (1997). A thousand and one roles for the Drosophila EGF receptor. Trends Genet. 13, 191-196.[Medline]
Sen, J., Goltz, J. S., Konsolaki, M., Schüpbach, T. and Stein, D. (2000). Windbeutel is required for function and correct subcellular localization of the Drosophila patterning protein Pipe. Development 127, 5541-5550.
Sen, J., Goltz, J. S., Stevens, L. and Stein, D. (1998). Spatially restricted expression of pipe in the Drosophila egg chamber defines embryonic dorsal-ventral polarity. Cell 95, 471-481.[Medline]
Shortridge, R. D. and McKay, R. R. (1995). Invertebrate phosphatidylinositol-specific phospholipases C and their role in cell signaling. Invert. Neurosci. 1, 199-206.[Medline]
Tepass, U. (1999). Genetic analysis of cadherin function in animal morphogenesis. Curr. Opin. Cell Biol. 11, 540-548.[Medline]
Thisse, B., Stoetzel, C., Gorostiza-Thisse, C. and Perrin-Schmitt, F. (1988). Sequence of the twist gene and nuclear localization of its protein in endomesodermal cells of early Drosophila embryos. EMBO J. 7, 2175-2183.[Abstract]
Van Buskirk, C. and Schüpbach, T. (1999). Versatility in signalling: multiple responses to EGF receptor activation during Drosophila oogenesis. Trends Cell Biol. 9, 1-4.[Medline]
Wassarman, D. A., Therrien, M. and Rubin, G. M. (1995). The Ras signaling pathway in Drosophila. Curr. Opin. Genet. Dev. 5, 44-50.[Medline]
Wasserman, J. D. and Freeman, M. (1998). An autoregulatory cascade of EGF receptor signaling patterns the Drosophila egg. Cell 95, 355-364.[Medline]
Xu, T. and Rubin, G. M. (1993). Analysis of genetic mosaics in developing and adult Drosophila tissues. Development 117, 1223-1237.