Abstract
Morphogenesis of the Drosophila embryo is associated with dynamic rearrangement of the actin cytoskeleton mediated by small GTPases of the Rho family. These GTPases act as molecular switches that are activated by guanine nucleotide exchange factors. One of these factors, DRhoGEF2, plays an important role in the constriction of actin filaments during pole cell formation, blastoderm cellularization, and invagination of the germ layers. Here, we show that DRhoGEF2 is equally important during morphogenesis of segmental grooves, which become apparent as tissue infoldings during mid-embryogenesis. Examination of DRhoGEF2-mutant embryos indicates a role for DRhoGEF2 in the control of cell shape changes during segmental groove morphogenesis. Overexpression of DRhoGEF2 in the ectoderm recruits myosin II to the cell cortex and induces cell contraction. At groove regression, DRhoGEF2 is enriched in cells posterior to the groove that undergo apical constriction, indicating that groove regression is an active process. We further show that the Formin Diaphanous is required for groove formation and strengthens cell junctions in the epidermis. Morphological analysis suggests that Dia regulates cell shape in a way distinct from DRhoGEF2. We propose that DRhoGEF2 acts through Rho1 to regulate acto-myosin constriction but not Diaphanous-mediated F-actin nucleation during segmental groove morphogenesis.
INTRODUCTION
The body plan of higher animals and insects is segmented to allow controlled patterning and growth in well-defined compartments. Segmentation is associated with the formation of boundaries between segments to prevent distinct populations of cells from intermingling and to allow them to be patterned separately during development. For example, the early Drosophila embryo is divided into 14 reiterated developmental units termed parasegments (Martinez-Arias and Lawrence, 1985; Lawrence and Struhl, 1996). Cells within each parasegment are sorted out from neighboring parasegments by the establishment of parasegment boundaries that are visible as transient grooves at the anterior of each stripe of cells expressing the segment polarity gene engrailed (en) (Vincent and O'Farrell, 1992). Another boundary, the segment boundary, forms posterior to each stripe of en expression. Formation of segment boundaries begins shortly after the initiation of germ band retraction, and is associated with distinct morphologic changes in segment border cells. These changes include apical constriction of the most posterior en-expressing cells that result in a local folding termed segmental groove. Formation of segmental grooves requires activity of the segment polarity genes en, hedgehog (hh), and wingless (wg). Embryos mutant for either en or hh fail to form segment boundaries, and continuous expression of these genes is essential for maintenance of the boundaries. Anterior to en-expressing cells, a wg-mediated inhibitory signal prevents cells from forming a groove (Larsen et al., 2003). However, how these patterning genes direct morphogenesis, and which cytoskeletal regulators control cell shape during this process is currently unknown.
Rho-guanosine triphosphatases (GTPases) play an important role in the control of cell shape changes that are driven by rearrangement of the actin cytoskeleton. In Drosophila, Rho1 has been shown to regulate cell shape and adhesion in many processes, such as cellularization (Padash Barmchi et al., 2005), gastrulation (Barrett et al., 1997; Häcker and Perrimon, 1998), epidermal development (Bloor and Kiehart, 2002), dorsal closure, segmentation, and head involution (Magie et al., 1999) as well as during epithelial folding in wing imaginal discs (Nikolaidou and Barrett, 2004). Activation of Rho1 requires the exchange of guanosine diphosphate for guanosine triphosphate, which is catalyzed by guanine nucleotide exchange factors (GEFs) such as DRhoGEF2.
The role of DRhoGEF2 in epithelial morphogenesis has been studied in most detail in early Drosophila embryos. During gastrulation, DRhoGEF2 regulates apical cell constriction that drives the invagination of mesodermal and endodermal primordia (Barrett et al., 1997; Häcker and Perrimon, 1998). Evidence identifying factors that connect DRhoGEF2 to the actin cytoskeleton has emerged from genetic studies. In the ventral mesoderm DRhoGEF2 and the Rho-effector Rho-kinase (DRok) are required for apical localization of myosin II, and mutants in both genes result in similar phenotypes (Dawes-Hoang et al., 2005). In Drosophila Schneider (S2) cells, DRhoGEF2-mediated cell contraction can be inhibited by DRok inactivation (Rogers et al., 2004). Thus, a Rho-effector pathway including DRok, the regulatory subunit of myosin light chain phosphatase (myosin binding subunit) (Mizuno et al., 2002; Tan et al., 2003) and myosin II that has been described in other systems (Amano et al., 1996) is thought to control acto-myosin contraction in response to DRhoGEF2 activation.
DRhoGEF2 is also required for stabilization and contraction of actomyosin filaments during blastoderm cellularization (Grosshans et al., 2005; Padash Barmchi et al., 2005), and mutants in DRhoGEF2 and DRok have similar defects during this process (Dawes-Hoang et al., 2005). DRok may therefore act as a DRhoGEF2-effector in a broad cellular context.
Another Rho1-effector, that plays an important role in early embryos and regulates F-actin nucleation and polymerization together with the actin binding protein Profilin (Wallar and Alberts, 2003) in a pathway parallel to DRok (Watanabe et al., 1997) is the Formin homology protein Diaphanous (Dia) (Afshar et al., 2000). In mammalian systems, mDia1 and the DRok homologue Rho-kinase (ROCK) have been shown to work concurrently during stress fiber formation. Interestingly, mDia1 and ROCK can induce stress fibers of different thicknesses and densities depending on the balance between their individual activities, indicating that the two Rho-effector pathways may be independently regulated (Watanabe et al., 1999).
It has been hypothesized that Rho-effector pathway specificity may be conferred by individual GEFs such as DRhoGEF2. However, whether DRhoGEF2 can activate Dia or signals specifically through DRok is currently unclear.
Here, we show that DRhoGEF2 and Dia regulate cell shape changes during segmental groove morphogenesis. Overexpression of DRhoGEF2 in epidermal cells is sufficient to induce cell contraction and premature formation of segmental grooves. Activation of the Formin Dia results in strengthening of cell junctions, and controls F-actin levels and cell shape in a manner distinct from DRhoGEF2. Our data suggest that DRhoGEF2 may select the outcome of Rho1-activation to regulate cortical myosin II recruitment and constriction of acto-myosin fibers but not cell adhesion or F-actin polymerization.
MATERIALS AND METHODS
Fly Strains
The following mutant alleles were used: DRhoGEF2l(2)04291 (Häcker and Perrimon, 1998), dia5 (Castrillon and Wasserman, 1994), and sqh-GFP (Royou et al., 2004). The following Gal4 drivers and their responders were used: prd-Gal4, en-Gal4-GFP, pnr-gal4 (Bloomington Drosophila Stock Center, Department of Biology, Indiana University, Bloomington, IN), twi-Gal4 (gift from A. Michelson, Department of Medicine, Brigham and Women's Hospital, Harvard Medical School, Boston, MA), wg-Gal4 (gift from N. Perrimon, Department of Genetics, HHMI, Harvard Medical School, Boston, MA), UAS-DRhoGEF2-RE (Padash Barmchi et al., 2005), and UAS-diaCA-HA (Somogyi and Rørth, 2004). Germline clones (GLCs) of DRhoGEF2L(2)04291 and dia5 were generated by using the autosomal flippase-mediated recombination dominant-female-sterile technique (Chou and Perrimon, 1996). Females carrying DRhoGEF2L(2)04291 GLCs were crossed to DRhoGEF2L(2)04291/Cyo-GFP males. Embryos maternally and zygotically mutant for DRhoGEF2L(2)0429 were identified by the absence of green fluorescent protein (GFP). Females carrying dia5 germline clones were crossed to dia5/CyO males and kept at 18°C.
Immunolocalization
For phalloidin stainings, embryos were dechorionated in 50% bleach, fixed in 4 ml of HEPES, 1 mM EGTA, 20 mM Mgso4, 4 or 8% formaldehyde, and 5 ml of heptane for 20 min, and then they were devitellinized by hand, washed in phosphate-buffered saline plus 0.1% Tween 20 (PBT), and incubated in rhodamine-conjugated phalloidin (Invitrogen, Carlsbad, CA) for 1 h, washed three times in PBT, and mounted on a microscope slide. Otherwise embryos were fixed as described above and methanol devitellinized. Primary antibodies used were as follows: rabbit anti-DRhoGEF2 (gift from S. Rogers, Department of Biology, The University of North Carolina at Chapel Hill, Chapel Hill, NC; 1/1000), rabbit anti-Dia (gift from S. Wasserman, Section of Cell and Developmental Biology, University of California at San Diego, La Jolla, CA; 1/2000), rat anti-hemagglutinin (HA) high-affinity (Roche Diagnostics, Indianapolis, IN; 1/100), rabbit anti-Sqh (gift from Tien Hsu, Medical University of South Carolina, Hollings Cancer Center, Charleston, SC; 1/50), mouse anti-Arm (Developmental Studies Hybridoma Bank, University of Iowa, Iowa City, IA; 1/200), rat anti-E-Cad (gift from H. Oda, JT Biohistory Research Hall, Osaka, Japan; 1/250), guinea pig anti-odd (gift from C. Rauskolb, Waksman Institute, Rutgers, the State University of New Jersey, Piscataway, NJ; 1/1000), or mouse anti-En (Developmental Studies Hybridoma Bank; 1/50). The secondary antibodies used were cyanine (Cy)2-goat anti-rabbit immunoglobulin (Ig)G, Rhodamine Red-X goat anti-mouse IgG, Cy2-goat anti-mouse IgG, Cy2-goat anti-rat IgG, Rhodamine Red-X goat anti-rat IgG, Rhodamine Red-X goat anti-rabbit IgG (Jackson ImmunoResearch Laboratories, West Gove, PA), and Alexa 647-goat anti-rabbit IgG (Invitrogen). Images were obtained from a laser scanning confocal microscope (model TCS SP2; Leica, Wetzlar, Germany), and they were processed with Adobe Photoshop software (Mountain View, CA).
Scanning Electron Microscopy
Embryos were collected at timed intervals, dechorionated, fixed in 2.5% glutaraldehyde for 2 h, and devitellinized with methanol. For visualizing filopodia, embryos were devitellinized by hand, using a needle. Embryos were then washed twice in 0.1 M sodium cacodylate, pH 7.4, postfixed in 1% osmiumtetroxide and 0.1 M sodium cacodylate, pH 7.4, for 1 h, and dehydrated in an ethanol series. After exchange of ethanol against carbon dioxide in a critical point dryer, embryos were mounted on stubs, gold-palladium coated in a sputter coater, and photographed in a JEOL LV5600 scanning electron microscope (SEM; JEOL, Tokyo, Japan).
RESULTS
Localization of DRhoGEF2, F-actin, and Myosin II during Segmental Groove Morphogenesis
DRhoGEF2, F-actin, and myosin II play important roles in the generation of acto-myosin–based contractile force, and they are dynamically redistributed during many morphogenetic processes (Nikolaidou and Barrett, 2004; Rogers et al., 2004; Dawes-Hoang et al., 2005). We investigated the localization of DRhoGEF2 with respect to F-actin and myosin II at the segmental grooves that first become apparent in the embryonic epidermis during stage 12, shortly after the onset of germband retraction. Groove formation occurs first in thoracic segments by dorsal-ventral elongation of the tracheal pits that are in register with segmental grooves, and it gradually proceeds toward more posterior segments in the course of germband retraction during stage 12. Formation of segmental grooves is initiated by apical constriction of a single cell row in each segment corresponding to the posterior-most en-expressing cells (Larsen et al., 2003). At the onset of groove formation, DRhoGEF2, F-actin, and myosin II are distributed along the apicolateral cortex in all epidermal cells (Figure 1, E–E″). Levels of F-actin and to a much lesser degree DRhoGEF2 were increased in groove founder cells (Figure 1, A–D′, arrowheads) that constrict apically and change shape from cuboidal to wedge shaped. Interestingly, F-actin accumulation was polarized in the plane of the epithelium because F-actin levels were consistently highest at the posterior boundary of groove founder cells (Figure 1, C, C′, D, and D′). A significant enrichment or polarization of myosin II in groove founder cells could not consistently be detected. Apical constriction of groove founder cells during early stage 12 results in the formation of shallow grooves. As the groove deepens, DRhoGEF2, F-actin, and myosin II begin to accumulate basally at the interface between epidermal cells and the underlying mesoderm (Figure 1, F–F″, arrows). Concomitantly, the epidermis is organized into a stratified columnar epithelium with a defined baseline. Grooves have a symmetrical appearance with the apically constricted groove founder cell at the center flanked by three to four cells on either side. No additional cells enter the groove after this stage; however, during the second half of stage 12 the groove continues to deepen as the basal end of cells moves further inside. Simultaneously, groove founder cells and their immediate neighbors elongate approximately twofold along their apical-basal axis (Figure 1, G, H, and H′, arrow).
Shortly after grooves reach their maximum depth at the end of stage 12, DRhoGEF2, F-actin, and myosin II accumulate posterior to the groove founder cell at the apical cortex of four to five cells that constrict their apices, and the grooves begin to regress (Figure 1, I, J, and J′, arrows), first at the ventral side followed by more lateral regions. In parallel to constricting their apices, cells elongate their apical-basal axis (Figure 1, K, L, and L′). This further reduces groove depth posterior to the segment boundary, giving the groove an asymmetrical morphology (Figure 1, I–L′). In the late phase of groove regression that lasts throughout stage 15, groove cells shorten their apical-basal axis, and they adopt a cuboidal shape (Figure 1, M, N, and N′). In summary, we identify five morphologically distinguishable phases during groove morphogenesis that include apical constriction that results in initial bending of the epithelium during early stage 12, apical-basal elongation of groove founder cells during late stage 12, apical constriction of cells posterior to the groove initiating groove regression during stage 13, apical-basal elongation of cells in the groove, and outward movement of the apical cell surface followed by subsequent apical-basal shortening and outward movement of the basal end of cells.
Groove regression temporally overlaps with the differentiation of denticles, which are F-actin–rich protrusions on the apical surface of cells in the ventral epidermis that together form the denticle belts of the mature larva. The cells that constrict during segmental groove regression coincide largely with cells that form denticles. It has been reported that denticle-forming cells undergo shape changes and accumulate F-actin and myosin II at their apical ends. After initial uniform distribution (Figure 1, I and J, arrows), F-actin and myosin II condense into polarized aggregates (Figure 1, K–N) at the posterior cell boundary that subsequently differentiate into denticles (Price et al., 2006; Walters et al., 2006). In contrast, DRhoGEF2 remains cortically enriched in more apicolateral regions (Figure 1, L′ and N′), and it is not found in F-actin condensations (Figure 1, O–O″ and P–P″, brackets). In addition, DRhoGEF2 accumulation also occurs in cells of the lateral epidermis that undergo the same cell shape changes as ventral cells, but do not form denticles (Figure 1Q, arrows). These observations are consistent with the view that DRhoGEF2 accumulation may play a role in the regulation of cell shape rather than denticle formation.
Embryos lacking DRhoGEF2 fail to recruit myosin II to the apical membrane of ventral furrow cells during gastrulation (Nikolaidou and Barrett, 2004; Dawes-Hoang et al., 2005). To investigate whether DRhoGEF2 is sufficient to recruit myosin II to the cell membrane, we expressed a UAS-DRhoGEF2-RE transgene (hereafter referred to as DRhoGEF2) (Padash Barmchi et al., 2005) in the epidermis by using prd-Gal4. This resulted in cortical accumulation of myosin II in cells of the prd domain (Figure 1, R–R″), suggesting that DRhoGEF2 may regulate apical myosin II localization also during segmental groove morphogenesis. An effect of DRhoGEF2 on F-actin accumulation could not be detected (Figure 3).
DRhoGEF2 Is Required for Formation and Regression of Segmental Grooves
DRhoGEF2 is maternally supplied to the embryo, and ubiquitously expressed in the zygote. In embryos that are zygotic mutant for the null allele DRhoGEF2l(2)04291, segmental grooves form but occasionally individual grooves fail to regress (Figure 4B), suggesting that DRhoGEF2 may play a role in groove regression. Among embryos derived from DRhoGEF2l(2)04291-mutant germline clones, two phenotypically distinct groups can be distinguished that correspond to maternally (DRhoGEF2M) or maternally and zygotically (DRhoGEF2MZ) mutant embryos. Embryos from either group develop with severe defects during early embryogenesis that make analysis of segmental groove formation very difficult. We therefore stained these embryos for En, which highlights the position at which segmental grooves form in the wild type. Our analysis revealed that despite the severe distortion of the epidermis that occurs in the absence of maternal DRhoGEF2, most segmental grooves form (Figure 2A). In contrast, fully developed grooves that are several cell diameters in depth were not observed in DRhoGEF2MZ mutants (Figure 2B). Analysis at the cellular levels showed that DRhoGEF2MZ embryos form shallow indentations in the epidermis that occasionally, but not always, coincide with the posterior-most en-expressing cell. However, cell shapes are randomized and cell size is irregular with many cells abnormally enlarged. Apical constriction of groove founder cells is not observed, and subsequent morphologic changes in epithelial cells such as apical-basal cell elongation do not occur (Figure 2C, arrowheads). F-actin is often distributed irregularly at the cortex of cells throughout the epithelium (Figure 2D, arrowheads). These results show that DRhoGEF2 is required for F-actin organization and the regulation of cell shape changes at the segmental grooves in the embryonic epidermis.
DRhoGEF2 Regulates Actomyosin Contraction
The irregular shape and size of cells in DRhoGEF2 mutants precluded a detailed analysis of cell behavior in this genetic background. To gain insight into the specific role of DRhoGEF2 in segmental groove morphogenesis, we overexpressed DRhoGEF2 in the epidermis by using prd-Gal4 because the prd domain overlaps with segment boundaries. In the wild type, parasegmental grooves become first apparent in the epidermis at embryonic stage 11. In prd-Gal4>UAS-DRhoGEF2-RE embryos, parasegmental grooves form prematurely in DRhoGEF2-overexpressing segments. Staining for En showed that parasegmental grooves form anterior to en-expressing cells, which is where they also form in the wild type (Figure 3, A and A′). Thus, DRhoGEF2 activation seems to enhance wild-type grooves rather than leading to the formation of ectopic or aberrantly shaped grooves.
Similar to parasegmental grooves, segmental grooves start to form prematurely during stage 12 in DRhoGEF2-overexpressing segments (Figure 3, B and B′). Groove founder cells overexpressing DRhoGEF2 initially constrict apically, similar to their wild-type counterparts, but then contract and assume a rounded shape (Figure 3, C and C′). Apical-basal elongation of groove founder cells does not occur, and this may contribute to a deepening of grooves that is observed in DRhoGEF2-overexpressing segments (Figure 3, C and C′, and D and D′). Contraction is not limited to groove founder cells but is observed in all DRhoGEF2-overexpressing cells (Figures 3, D and D′ and E and E′; and 4G, arrowheads) consistent with a previous report showing that DRhoGEF2-overexpression induces contractility in Drosophila S2 cells (Rogers et al., 2004).
In addition to an approximately twofold increase in groove depth, DRhoGEF2 overexpression results in delayed groove regression (Figure 3, D and D′ and E and E′), and grooves persist at a time when the wild-type epidermis has returned to a smooth appearance (Figure 4, A and C).
The premature onset of groove invagination and the preservation of normal groove morphology suggest that increased DRhoGEF2-induced contractility at least in part enhances normal aspects of cell behavior and that it can be used to modulate the forces contributing to groove formation. A question that has remained unanswered in the context of groove formation is whether grooves are formed autonomously by shape changes of epidermal cells or whether pulling forces in underlying tissues contribute to furrowing. To address this issue, we expressed DRhoGEF2 exclusively in the mesoderm by using twi-Gal4 as a driver. Interestingly, no effect on groove formation was observed. Grooves did not form prematurely (Figure 3F), groove depth remained unchanged (Figure 3G), and groove regression occurred normally as in wild type (Figure 3H). In contrast, when DRhoGEF2 was overexpressed exclusively in the dorsal ectoderm by using pnr-Gal4, the DRhoGEF2-expressing areas of the epidermis formed deep grooves that persisted throughout dorsal closure of the embryo (Figures 3I and 4, E, F, and F′). These observations suggest that modulation of contractile force in the ectoderm, but not in the underlying mesodermal tissue, can contribute to groove invagination in a cell-autonomous manner.
Role of Diaphanous in Segmental Groove Morphogenesis
To identify other cytoskeletal regulators involved in segmental groove morphogenesis, we investigated Dia, which plays a role in other DRhoGEF2-dependent processes such as pole cell formation and cellularization (Afshar et al., 2000). Dia is distributed throughout the epidermis and enriched at the vertices of epithelial cells, were elevated levels of the adherens junction (AJ) protein Armadillo (Arm) and F-actin are also found (Figure 5, A and A′, arrowhead; and C and C′). We found that Dia accumulates apicolaterally in groove founder cells at the onset of groove invagination (Figure 5, B and B′, arrowhead). Similar to F-actin, Dia accumulation is polarized to the posterior boundary of groove founder cells consistent with the view that Dia may control F-actin nucleation in these cells (Figure 5, C and C′).
dia is contributed maternally to the egg and homozygous mutant dia embryos show no defects during segmental groove formation. Embryos derived from females that completely lack dia function in the germline cannot be analyzed due to severe cytokinesis defects (Castrillon and Wasserman, 1994). We therefore analyzed the strong hypomorphic allele dia5 in which dia protein levels are severely reduced (Figure 5, D and D′). Embryos derived from females homozygous for dia5 in the germline develop with severe morphologic defects and die at the end of embryogenesis. Staining of these embryos for En and F-actin suggested that segmentation occurs normally, however, cells throughout the epidermis were enlarged, irregular in shape and many cells were multinucleated (Figure 5G, arrowheads). F-actin was localized at the cortex but often distributed in irregular aggregates (Figure 5, D′ and E′). In addition, the homotypic adherens junction protein E-Cadherin (E-Cad) was lost from the cell cortex in some areas (Figure 5, E–E″), suggesting a role for dia in the maintenance of adherens junctions. In the majority of embryos, no segmental grooves were observed and a coordinated sequence of specific cell shape changes at the segment boundaries could not be identified (Figure 5, H and H′). In a small subset of embryos (∼25%) grooves formed despite the abnormal shape of cells, which is likely due to partial rescue by paternally contributed dia (Figure 5, I and I′). We conclude from these observations that dia is required for segmental groove formation.
To investigate the function of Dia in groove founder cells and to compare the specific role of Dia to DRhoGEF2, we expressed constitutive active diaCA (Somogyi and Rørth, 2004) in the embryonic epidermis. Expression of diaCA by using prd-Gal4 resulted in premature formation of segmental grooves that were significantly deeper than in the wild type (Figure 6A), and they persisted at stages when wild-type grooves had regressed (Figure 4D). Expression of diaCA by using wg-Gal4 was able to induce apical constriction in cells that do not constrict in the wild type (Figure 6B, arrowheads, and C–F′), showing that similar to DRhoGEF2, the ability of diaCA to induce cell shape changes is not restricted to cells in the groove.
The morphology of diaCA-expressing grooves was significantly different from DRhoGEF2-overexpressing grooves (Figure 6A), indicating that Dia activation promotes a different type of cell shape change. In contrast to DRhoGEF2-overexpressing cells, diaCA-expressing cells did not round up, but they retained a columnar shape (Figures 4H, arrowheads; and 6H). Similar to DRhoGEF2-overexpressing cells, diaCA-expressing cells at the center of the groove did not elongate their apical-basal axis. To investigate whether dia stabilizes cell junctions we stained diaCA-expressing embryos for E-Cad and the β-catenin homologue Armadillo (Arm). We found that E-Cad and Arm accumulated at the apical membrane of diaCA-expressing cells (Figure 6, C–F). No changes in E-Cad or Arm were observed upon DRhoGEF2-overexpression. diaCA-expression, also caused accumulation of F-actin that was strongest in apicolateral membrane domains (Figure 6H, arrowhead) and colocalized with E-Cad and Arm at AJs (Figure 6, D, D′, F, and F′).
Dia has previously been implicated in maintenance of myosin II at contractile acto-myosin filaments (Dean et al., 2005). To investigate whether Dia affects myosin II in the embryonic epidermis, we expressed diaCA by using wg-Gal4 and we found that myosin II levels were increased at the membrane of diaCA-expressing cells (Figure 6, G and G′, arrowheads).
Similar to previous reports diaCA-expression induced extensive filopodia formation at the surface of cells (Figures 4, I and J, arrowhead; and 6, J and J′, arrowhead). In the large amnioserosa cells, Dia was localized at the apical tip of filopodia (Figure 6I, arrowhead) where it has also been described in other systems (Schirenbeck et al., 2005; Williams et al., 2007). Filopodia can also be induced by inactivation of DRok downstream of RhoV14 (Williams et al., 2007) consistent with the possibility that a balance of activity between the Dia and Rho-kinase pathways may regulate filopodia formation. We found that DRhoGEF2 mutant cells in the invaginating ventral furrow, and to a lesser degree also cells in the epidermis (data not shown), form large numbers of filopodia-like protrusions (Figure 4M) consistent with the view that DRhoGEF2 may inhibit filopodia, whereas Dia may promote their formation. To test this hypothesis, we coexpressed DRhoGEF2 and diaCA using prd-Gal4. Interestingly, this resulted in the formation of extremely deep segmental grooves (Figure 6, K and K′), indicating an additive effect of Dia and DRhoGEF2. Cells took on a rounded shape characteristic for DRhoGEF2 overexpression (Figure 4K) and at the same time they accumulated high levels of F-actin that was uniformly distributed at the cell cortex (compare Figure 6, J and J′ with L and L′). Formation of filopodia was not observed. Together, our data suggest that activation of DRhoGEF2 or Dia results in distinctly different reorganizations of the actin-based cytoskeleton.
DISCUSSION
Forces Controlling Segmental Groove Morphogenesis
Our analysis of segmental groove morphogenesis revealed that during invagination groove founder cells undergo two distinct phases of shape change. Initial apical constriction is associated with accumulation of F-Actin, DRhoGEF2 and Dia at the site of groove initiation. Together with the loss of apical constriction in DRhoGEF2 or dia mutants and the observation that DRhoGEF2 or diaCA-overexpressing grooves form earlier, are deeper, and persist longer than wild-type grooves, this indicates that contractile forces in epidermal cells provide a driving force for groove morphogenesis.
Subsequent to apical constriction, groove founder cells and their immediate neighbors elongate their apical-basal axis and extend their basal sides inward. Apical-basal elongation does not occur when DRhoGEF2 or diaCA are overexpressed, suggesting that activation of these factors may counteract this specific change in cell shape. Inward movement of the epithelial baseline is not affected, and it occurs to a similar depth as in wild type, suggesting that it is not resulting from a pushing force generated by cell elongation. Expression of DRhoGEF2 in underlying mesodermal cells does not affect groove formation. Thus, cell autonomous bending of the epithelium rather than a pulling force originating in underlying tissues may be the main contributor to groove invagination.
It has been suggested that germband retraction that occurs in parallel to segmental groove formation may contribute to the forces that cause groove founder cells to invaginate (Larsen et al., 2003). In DRhoGEF2 mutants, the posterior midgut primordium remains at the posterior pole due to failure of the endoderm to invaginate (Barrett et al., 1997; Häcker and Perrimon, 1998). Consequently, the germband is thrown into deep folds that illustrate the pressure exerted on the epithelial sheet. Yet, segmental grooves do not form in these embryos. Furthermore, local expression of DRhoGEF2 causes the formation of deep grooves in expressing cells but not in neighboring tissues. These observations do not exclude that global tissue rearrangements support segmental groove invagination, but they suggest that the major contributing force to groove formation is due to autonomous action of epidermal cells.
At the onset of stage 13 when germband retraction has completed, DRhoGEF2, F-actin, and myosin II accumulate apically in four to five cells posterior to the grooves. These cells subsequently constrict apically, which may bend the epithelium in an outward direction. Thus, groove regression may be actively driven by actomyosin-based constriction of epidermal cells. This is supported by previous findings showing that in zipper mutants, which partially lack nonmuscle myosin, grooves occasionally do not regress (Larsen et al., 2003).
Groove regression coincides with the formation of denticles in ventral epidermal cells posterior to the groove (Price et al., 2006; Walters et al., 2006). Denticle forming cells undergo cell shape changes that are followed by polarized accumulation of F-actin, myosin II, and Dia into condensations at the posterior cell boundary. Our analysis showed that DRhoGEF2 in contrast to Dia and myosin II, does not polarize to the F-Actin condensations and DRhoGEF2 mutants are able to form denticles (Padash Barmchi et al., 2005). DRhoGEF2 is therefore unlikely to play a role in denticle formation. We propose that the narrowing of cells along the anterior-posterior axis that occurs throughout the ventral and lateral epidermis before hair formation may be due to DRhoGEF2-controlled cell contraction and may contribute to the regression of segmental grooves.
In conclusion, our data suggest that groove invagination and regression are active processes driven by acto-myosin-based contractile filaments in epidermal cells that are regulated by DRhoGEF2 and Dia in a concentration-dependent manner.
DRhoGEF2 Effector Pathways in Segmental Groove Morphogenesis
The small GTPase Rho1 regulates acto-myosin constriction through a pathway including Rho-kinase (Winter et al., 2001), the regulatory subunit of myosin light chain phosphatase (Mizuno et al., 2002; Tan et al., 2003) and myosin II. DRhoGEF2 regulates cell contraction in different developmental contexts and DRhoGEF2-mediated recruitment of myosin II to the apical cortex and cell contraction require Rho-kinase (Rogers et al., 2004; Dawes-Hoang et al., 2005), suggesting that DRhoGEF2 controls acto-myosin contraction through the Rho-kinase pathway.
Rho1 also regulates F-actin nucleation and polymerization through a pathway including Dia and the actin-binding protein Profilin (Wallar and Alberts, 2003). In cell culture systems, mammalian Dia1 has been shown to act as a positive feedback regulator of Rho-activity through direct interaction with the C terminus of the mammalian DRhoGEF2 homologue LARG (Kitzing et al., 2007). However, it is not clear whether Dia can act as an effector of DRhoGEF2 during morphogenesis in vivo. Drosophila Dia is required in processes such as metaphase furrow invagination, pole cell formation and cellularization (Afshar et al., 2000) that are also defective in DRhoGEF2 mutants consistent with the idea that both proteins may function in concert.
Our data suggest that DRhoGEF2 and Dia are required for segmental groove morphogenesis. Interestingly, morphologic changes elicited by DiaCA at the epithelial and cellular level were distinct from those observed with DRhoGEF2. Whereas DRhoGEF2-overexpression caused cells to contract and take on a rounded shape, thereby reducing contact with each other, diaCA-expressing cells remained tightly packed and columnar. In addition, cells showed increased levels of the junctional proteins β-catenin and E-cadherin, suggesting a strengthening of cell–cell contacts. Consistent with this, mammalian Dia1 has been implicated in maintenance and stabilization of adherens junctions. In contrast, Rho-kinase-mediated generation of contractile force leads to the physical disruption of cell–cell contacts and cell rounding reminiscent of DRhoGEF2 overexpression (Sahai and Marshall, 2002). Another distinguishing feature between DRhoGEF2 and dia is the accumulation of F-actin in response to diaCA expression that is consistent with the role of Dia in nucleation and elongation of F-actin filaments. F-actin accumulation was not observed in response to DRhoGEF2-overexpression consistent with the view that DRhoGEF2 regulates F-actin contraction but not polymerization. We find that DRhoGEF2 and Dia have qualitatively different effects on F-actin remodeling, supporting the view that they may be connected to the actin cytoskeleton by distinct Rho-effector pathways. Despite the differences, overexpression of either DRhoGEF2 or diaCA in some instances seems to result in increased contractility. In DRhoGEF2, this is likely due to direct regulation of acto-myosin contractility through the Rho-kinase pathway. In DiaCA, the increased levels of actin elicited by Dia activation might indirectly promote the formation of acto-myosin filaments. Alternatively, DiaCA could affect contractility through its effect on myosin.
Expression of either diaCA or DRhoGEF2 led to increased myosin II levels. In Schneider cells, DRok activity and myosin phosphorylation were found to be required for myosin II recruitment to contractile acto-myosin fibers, whereas Dia was required for maintenance of myosin at contractile rings (Dean et al., 2005). Similar to Rho-kinase, DRhoGEF2 is required for apical recruitment of myosin II in the ventral furrow during gastrulation (Dawes-Hoang et al., 2005). A role of Dia in this process has not been reported but it is possible that DRhoGEF2 and Dia may regulate different aspects of myosin function also in the Drosophila embryo.
In summary, we find that DRhoGEF2 and Dia are required for segmental groove formation and that they may act in concert to regulate a series of specific cell shape changes that lead to groove invagination. However, clear differences in the response of cells to activation of DRhoGEF2 or Dia at the morphologic and molecular level suggest that both genes may regulate the actin cytoskeleton through distinct effector pathways.
ACKNOWLEDGMENTS
We thank Rita Wallén for help with scanning electron microscopy and Drs. Hsu, Karess (CNRS, Centre de Génétique Moléculaire, Gif-sur-Yvette, France), Oda, Rauskolb, Rogers, Rørth (Temasek Life Sciences Laboratory, Singapore), Vincent (MRC National Institute for Medical Research, London, United Kingdom), and Wasserman; the Bloomington Drosophila Stock Center; and the Developmental Studies Hybridoma Bank for reagents. This work was supported by the Swedish Cancer Foundation, The Swedish Research Council, the Thorsten and Elsa Segerfalk Foundation, the Crafoord Foundation, and the Nilsson-Ehle Foundation.
Note added in proof.
We state that a role for Dia in gastrulation has not been reported. Since submission of this manuscript Homem and Peifer (2008) have reported such a role and also describe a function for Dia in the regulation of myosin and adherens junctions similar to our data.
Footnotes
This article was published online ahead of print in MBC in Press (http://www.molbiolcell.org/cgi/doi/10.1091/mbc.E07-12-1230) on February 20, 2008.
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