Centre for Cellular and Molecular Biology, Uppal Road, Hyderabad, 500 007 India
* Author for correspondence (e-mail: shashi{at}ccmb.res.in)
Accepted 28 April 2005
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Summary |
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Key words: Hedgehog, Cell polarity, Peripodial membrane, Notch, A/P axis
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Introduction |
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Here we examine the morphology of PM cells in the context of their signaling capabilities. Cell polarity plays an important role in the polarized transport of signaling molecules. In the eye imaginal disc, HH and Ser are expressed in PM, yet they control the activation of corresponding pathways in DP (Cho et al., 2000; Gibson and Schubiger, 2000
). Both HH and N pathway activation involves cell-cell interactions at the apical ends of epithelial cells. We made use of proteins that mark different spatial domains along the apico-basal axis of epithelial cells. For example, actin is an apical marker, Armadillo (ARM) marks the subapical region, and fasciclin III (FASIII) and Discs-large (DLG) mark basolateral sides of the cell (Woods et al., 1997
). While cell polarity is an established feature of epithelial cells, no such characterization is reported for PM, probably because of the squamous nature of cells of this epithelial layer. PM and DP cells diverge from a common set of precursor cells at the first larval instar stage (Pallavi and Shashidhara, 2003
). Thus, although PM and DP cells have distinct morphological differences, it is likely that they are similarly polarized. However, in the context of signaling interaction between the two membranes, the relevant question here is the orientation of PM and DP cells vis-à-vis their cell polarity. With the help of the above-mentioned polarity-specific cell markers, we have observed that apical surfaces of PM and DP cells face each other. Overexpression of Delta (Dl; a membrane-bound ligand of the Notch (N) receptor) in PM cells causes ectopic activation of Wingless (WG; a target of N pathway in the wing pouch) in DP cells, thus providing a functional validation of PM and DP organization with respect to their cell polarity.
Cell-cell interactions in the epithelial cells are best demonstrated in the Drosophila wing disc in the context of its patterning along the anterior-posterior (AP) and the dorsal-ventral (DV) axes. The HH pathway is required for patterning along the AP axis, whereas the Notch (N) pathway regulates patterning events along the D/V axis. However, elucidation of these cell-cell interactions is entirely related to events in the disc proper, whereas patterning events in PM are not well understood. Possible differences between PM and DP in these events are indicated in the reports that DPP diffused from the DP acts as a survival signal for PM cells (Gibson et al., 2002) and suppression of WG and epidermal growth factor receptor signaling at early stages of wing specification helps PM cells to acquire squamous morphology (Baena-Lopez et al., 2003
). The complete absence of Apterous (AP) and WG expression in PM (Pallavi and Shashidhara, 2003
) suggests ventral identity to all PM cells. In DP cells, A/P boundary is specified by the activity of HH, which diffuses from the posterior compartment to the anterior compartment. In the presumptive A/P boundary, HH activates Cubitus-interruptus (CI) by stabilizing its full-length isoform, which in turn activates DPP expression. DPP is not activated in the posterior compartment because of direct inhibition of CI by Engrailed (EN) (reviewed by Aza-Blanc and Kornberg, 1999
; Ingham and McMahon, 2001
). Our results reported here suggest that, unlike DP cells, EN-expressing PM cells do not express HH. However, similar to DP cells, EN-expressing PM cells express DPP in response to ectopic expression of CI, but they do not respond to ectopic HH. Ectopic expression of HH in the PM, however, can activate DPP in the anterior compartment of DP.
Finally, we made use of PM-DP interactions to re-examine the movement of HH protein between epithelial cells. We expressed wild-type HH and two mutant forms of HH, which are not cholesterol modified (one of them being also a membrane-tethered form of HH) in PM cells and examined the effect on DP using DPP expression as the read-out. Our observations suggest that diffusion of wild-type HH requires direct cell-cell contact and confirms earlier observations that cholesterol modification of HH causes its restricted diffusion.
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Materials and Methods |
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Histology
Immunohistochemical staining was essentially as described by Patel et al. (Patel et al., 1989). Rhodamine-labeled phalloidin (to visualize F-actin) was purchased from Molecular Probes, USA. The primary antibodies used are, anti-ARM (Riggleman et al., 1990
), anti-ß-galactosidase (Sigma, St Louis, USA), anti-CI (Motzny and Holmgren, 1995
), anti-DLG (Parnas et al., 2001
), anti-EN (Patel et al., 1989
), anti-FASIII (Patel et al., 1987
), anti-HH (gift from T. Tabata, Tokyo, Japan), anti-pMAD (Persson et al., 1998
), anti-PTC (Capdevila et al., 1994
), anti-UBX (White and Wilcox, 1984
) and anti-WG (Brook and Cohen, 1996
). Anti-ARM, anti-DLG, anti-EN, anti-FASIII and anti-WG antibodies were obtained from the Development Studies Hybridoma Bank, University of Iowa, USA. Confocal microscopy was on Zeiss LSM/Meta.
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Results |
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First, the distribution of DLG and ARM in peripodial cells was visualized by confocal microscopy. As one starts taking optical sections (with a step size of 0.2 µm; average thickness of PM cells is 1.8 µm) in the region corresponding to PM from the uppermost surface of an unmounted wing disc and moves towards the DP, DLG staining is observed first followed by ARM (Fig. 2A1). Even when DLG staining fades off almost completely, ARM is still observed (Fig. 2A2), suggesting distinct cell-polarity of PM cells. Optical sections through the entire depth of an unmounted wing disc along its Z-axis showed that DLG, FASIII, ARM and actin are localized in that order in a PM cell as we move from the surface towards DP (Fig. 2B-E). All these markers further showed that PM and DP cells are oriented with their apical sides facing each other. Thus, a cross-section of the wing disc along its Z axis first shows DLG staining, then FASIII, ARM and actin in PM cells, which is followed by actin, ARM, FASIII and DLG in that order for DP cells (Fig. 2B-E). The same was evident in the optical sections of an eye imaginal disc (data not shown).
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Interestingly, we did not observe any activation of WG in cells at the medial edge of the wing disc PM, which do not express Ubx-GAL4. It has been shown earlier that repression of WG early during development is a prerequisite to specify peripodial fate (Baena-Lopez et al., 2003). It is possible that the mechanism operating in PM cells to repress WG is downstream of the N signaling pathway.
Patterning of PM along the anterior-posterior axis
The majority of PM cells (with the exception of medial edge cells) express UBX and are derived from UBX-expressing parasegment 6, from which posterior T2 and anterior T3 develop (Pallavi and Shashidhara, 2003). In addition, all UBX-expressing PM cells also express EN (Pallavi and Shashidhara, 2003
) (Fig. 4A-A'). These observations confirm posterior identity of UBX-expressing PM cells.
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CI is repressed by EN in the posterior cells of the disc proper and hence they do not respond to HH signaling. However, overexpression of CI in the posterior compartment causes ectopic DPP expression and thereby pattern duplications. Similar to these patterning events in DP cells, overexpression of HH using the PM-specific Ubx-GAL4 driver did not activate DPP in PM cells (see below), whereas overexpression of the full-length (activator) form of CI induced ectopic DPP expression in PM cells (Fig. 4F). These observations indicate that downstream of EN, both types of epithelial cells (PM and DP) have a similar hierarchy of gene regulation during patterning along the anterior-posterior axis.
The absence of HH and CI expression in PM cells, however, raises the question regarding the mechanism of DPP expression in those cells. Patched (PTC), the receptor of HH, is also a target of HH signaling. Antibody staining for PTC did not reveal any expression in PM cells (Fig. 4G), although a ptc-GAL4 driver showed expression in PM cells (data not shown). Moreover, overexpression of PTC, which antagonizes HH signaling (Johnson et al., 1995; Chen and Struhl, 1996
), using Ubx-GAL4 driver did not affect DPP expression in PM (Fig. 4H). It is possible that the disc proper may influence DPP expression in the peripodial membrane. However, overexpression of HH only in DP using the 426-GAL4 driver, a DP-specific GAL4 driver (Fig. 4I) (Pallavi and Shashidhara, 2003
), did not induce ectopic DPP expression in PM cells (Fig. 4J,J'). Thus, the mechanism of activation of DPP expression in PM cells remains unclear and requires further investigation.
Nevertheless, our observations bring out significant similarities (the absence of any response to ectopic HH by EN/UBX-expressing PM cells; activation of DPP expression in PM cells in response to ectopic CI) and differences (absence of HH expression in EN/UBX-expressing PM cells) between PM and DP of the wing disc. These observations, along with morphological differences in cell shapes, and the established signaling between the two membranes strengthens the utility of DP and PM as a unique model system to study epithelial cell interactions and molecular mechanism/s of related signal transduction pathways.
Overexpression of Hedgehog in PM activates DPP expression in the pouch but not in the notum
The Hedgehog family of proteins comprises short-range morphogens. Drosophila HH and vertebrate Sonic Hedgehog (SHH) are known to tether to the membrane with the help of covalently attached cholesterol (Porter et al., 1996), although small amounts of HH/SHH are known to be present in soluble fractions (Zeng et al., 2001
). Furthermore, HH diffuses from the apical side of posterior cells and is received at the apical side of anterior cells (Stringini and Cohen, 2000; Gallet et al., 2003
). Consistently, the localization of PTC receptor has been shown to be at the apical side of the cells (Capdevila et al., 1994
; Denef et al., 2000
). As both PM and DP are made up of epithelial cells with their apical ends facing each other and the two layers maintain cell-cell contacts in the pouch and connect via long microtubular extensions in the notum, overexpression of HH in PM would be a good assay system to study morphological requirement for the diffusion of HH. Furthermore, the absence of endogenous HH signaling in PM cells would be an advantage as there would not be any interference to the ectopically expressed HH. We used the expression of DPP (monitored using dpp-lacZ) as a molecular readout of HH pathway. Overexpression of HH using UAS-HH (it expresses wild-type cholesterol-modified HH) (Ingham and Fietz, 1995
) only in PM using Ubx-GAL4 driver induced overgrowth of DP, which was restricted only to the anterior wing pouch (Fig. 5B). We also observed strong ectopic expression of DPP in a large number of DP cells spread all over the anterior wing pouch (Fig. 5B) (as mentioned above, ectopic HH did not induce DPP expression in PM cells). The levels of pMAD were also significantly high in the entire anterior wing pouch (Fig. 5D). WG expression patterns in these discs were unaffected (Fig. 5E), suggesting that the overall patterning events in these discs were normal and there was no mixing of PM and DP cells (PM cells do not express WG). However, we did not observe such ectopic DPP or pMAD in the anterior notum (Fig. 5B,D). It is possible that notum cells are intrinsically not sensitive to overexpression of HH. However, overexpression of HH directly in the notum using a DP-specific GAL4 driver showed ectopic DPP staining in the notum (Fig. 4J). Therefore, the absence of ectopic DPP in the notum in the above-mentioned experiment is probably due to the inability of HH to diffuse from PM to the notum.
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Discussion |
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Apical-basal polarity in PM cells
Many morphogens are present on the apical surfaces of the cells and are secreted to the adjoining, adjacent cells where they lead to the activation of the signaling cascade by binding to their respective receptors. The receptors too are found at the apical surfaces and thus apical surfaces of epithelial cells are the sites of signaling activities. Here we have shown that PM cells have their polarity reversed with respect to the polarity of DP cells. Thus, the two types of cells have their apical sides facing each other (Fig. 3E). As PM and DP arise from a common pool of embryonic precursor cells (Pallavi and Shashidhara, 2003), it is intriguing how the two cell layers have such an arrangement. It is possible that the imaginal primordium first forms a single layer of disc epithelium, which may fold over itself into a saclike structure, such that the overlying cells will have their apical side facing the apical side of underlying cells. Specification of the overlying cells as peripodial membrane with squamous epithelial morphology may precede or be concurrent to this folding event. With the help of ectopic activation of the N pathway in PM, we have shown that the apical domain of PM cells does function as a signaling site and thereby could activate WG expression in the underlying DP. Thus, the arrangement of PM and DP cells vis-à-vis cell polarity confirms the potential of PM cells to signal to DP cells.
Patterning of PM along the A/P axis
Both peripodial and disc epithelia are derivatives of a single embryonic imaginal primordium. However, peripodial epithelium does not express WG or VG, which are required for the specification of the wing pouch, nor does it express Iro-C complex genes (Baena-Lopez et al., 2003), which specify notum identity. Nevertheless, PM cells show similarity to DP cells at the levels of patterning events along the AP axis. Only a part of the PM expresses EN. In particular, medial edge cells do not express EN. Between EN+ and EN- PM cells is a stripe of DPP-expressing cells, which may mark the AP boundary of the peripodial epithelium. Similar to EN+-DP cells, EN+-PM cells do not express DPP even when we overexpress HH, but they express DPP in response to over expression of CI. However, in the absence of HH and CI expression in PM cells, it is intriguing how DPP is expressed in a narrow row of cells abutting EN+ and EN- PM cells. Furthermore, overexpression of PTC in PM cells did not affect DPP expression, suggesting a possibility that DPP expression in PM cells is independent of HH function. Thus, regulation of DPP expression observed in a small subset of PM cells needs further investigation. Nevertheless, differences at the morphological level and certain similarities in patterning events between PM and DP further strengthen their utility as a model system.
Interestingly, CI-induced ectopic DPP in the PM did not affect growth properties (Fig. 4F) nor the levels of pMAD (data not shown) in DP. It is possible that activation of DPP in few PM cells may not imbalance the growth of DP cells. However, even overexpression of a DPP::GFP fusion protein (Teleman and Cohen, 2000) directly in PM cells did not affect the growth properties of DP cells, nor did we detect any GFP in those cells (data not shown). These results, thus, suggest that DPP cannot diffuse from PM to DP. Earlier reports suggest that DPP movement is mediated by an endocytic pathway (Gonzalez-Gaitan and Jackle, 1999
; Entchev et al., 2000
; Arquier et al., 2001
; Bharathi et al., 2004
). However, a recent report suggests that DPP moves along the cell surface by restricted extracellular diffusion, which is regulated by glypican proteins Dally and Dally-like (Belenkaya et. al., 2004
). In either case (glypican-regulated or endocytosis-mediated movement of DPP), PM cells may not support movement of DPP, although they are capable of receiving DPP signals from DP (Gibson et al., 2002
). Interestingly, PM cells do express Dally, a protein required for the diffusion of DPP (K. Makhijani and L.S.S., unpublished observations). It would be interesting to know what mechanisms operate to make DPP diffusion unidirectional. Again, PM and DP may prove to be useful system to study directional movement of such signaling molecules.
Cholesterol modification causes restricted diffusion of Hedgehog
As both PM and DP are made up of epithelial cells with their apical ends facing each other, overexpression of HH in PM would be a good assay system to examine the mechanism of diffusion of HH. The absence of endogenous HH signaling in PM cells would be an added advantage because there would not be any interference to the ectopically expressed HH. Cholesterol modification of HH is believed to be required for its efficient sequestration rather than for signaling per se (Burke et al., 1999). However, recently it has been suggested that cholesterol modification of HH helps in its localization to the apical ends of epithelial cells and is responsible for the activation of only a subset of HH targets (Gallet et al., 2003
).
We tested the ability of three different forms of HH, when overexpressed exclusively in PM cells, to activate DPP in DP cells: the wild-type HH, which is cholesterol modified, and two mutant forms, which are not cholesterol modified. Of the latter two, HH-N is mutant only for cholesterol modification (Gallet et al., 2003), whereas HH::CD2 is derived by fusing HH-N protein to the transmembrane domain of the rat CD2 protein (Stringini and Cohen, 1997). HH::CD2 thus lacks cholesterol modification and also does not freely diffuse between cells. It can signal only when the producing and receiving cells make direct cell-cell contacts. We have observed that all the three forms of HH are capable of activating DPP in the pouch, where both the membranes are juxtaposed to each other. In the notum, however, only HH-N could induce DPP expression. Previous reports suggest that cholesterol modification of HH is required for its apical targeting in expressing cells (Gallet et al., 2003
). In their experiments, HH-N could partially activate WG (a target of HH in the anterior compartment) expression, whereas HH::CD2 failed to activate WG. The authors have attributed this to the inability of the mutant forms of HH to localize to the apical ends of producing cells (Gallet et al., 2003
). In our assay system, we have observed that both HH-N and HH::CD2 could activate DPP expression in the anterior pouch, when expressed in PM cells. However, overexpression of HH-N and not HH::CD2 in PM cells could activate DPP expression in the anterior notum. Thus, our observations suggest that cholesterol modification on HH necessitates cell-cell contact and confirms earlier reports that cholesterol modification makes HH a short-range signaling molecule.
Overexpression of wild-type HH caused activation of DPP in the entire anterior compartment of the pouch as one continuous domain of expression, whereas misexpression of HH::CD2 caused activation of DPP in small patches. HH::CD2 is membrane tethered and therefore it cannot diffuse and is capable of activating DPP only at the places of direct contact between the two layers. Thus, cells that show DPP expression in the anterior pouch in response to HH::CD2 expression in PM may correspond to those DP cells that form direct contacts with PM cells. Previous reports suggest that PM and DP cells are in 1:80 ratio in the wing disc (Pallavi and Shashidhara, 2003). Although PM cells are large enough to cover the entire DP, it is possible that only a subset of PM cells actually make contacts (of functional significance) with DP cells. Such mapping of cell-cell contact points between PM and DP may provide a useful tool for further studies on possible role/s of PM in patterning wing pouch.
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Acknowledgments |
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