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Cdc42 controls spindle orientation to position the apical surface during epithelial morphogenesis
Correspondence to A. Hall: halla{at}mskcc.org
The establishment of apical–basal polarity within a single cell and throughout a growing tissue is a key feature of epithelial morphogenesis. To examine the underlying mechanisms, the human intestinal epithelial cell line Caco-2 was grown in a three-dimensional matrix to generate a cystlike structure, where the apical surface of each epithelial cell faces a fluid-filled central lumen. A discrete apical domain is established as early as the first cell division and between the two daughter cells. During subsequent cell divisions, the apical domain of each daughter cell is maintained at the center of the growing structure through a combination of mitotic spindle orientation and asymmetric abscission. Depletion of Cdc42 does not prevent the establishment of apical–basal polarity in individual cells but rather disrupts spindle orientation, leading to inappropriate positioning of apical surfaces within the cyst. We conclude that Cdc42 regulates epithelial tissue morphogenesis by controlling spindle orientation during cell division.
Abbreviations used in this paper: aPKC, atypical PKC; CFTR, cystic fibrosis transmembrane receptor; CTX, cholera toxin; E-cadherin, epithelial cadherin.
© 2008 Jaffe et al. This article is distributed under the terms of an Attribution–Noncommercial–Share Alike–No Mirror Sites license for the first six months after the publication date (see http://www.jcb.org/misc/terms.shtml). After six months it is available under a Creative Commons License (Attribution–Noncommercial–Share Alike 3.0 Unported license, as described at http://creativecommons.org/licenses/by-nc-sa/3.0/).
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Introduction |
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 TopAbstract Introduction Results and discussionMaterials and methodsReferences |
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Epithelial morphogenesis involves the establishment of an apical surface in an individual cell and the formation of cadherin-based adherens junctions and claudin-based tight junctions between adjacent cells. Accompanying reorganization of the actin and microtubule cytoskeletons and polarized vesicle trafficking reinforces these interactions, leading to a stable tissue of polarized cells. Expression of dominant-negative or constitutively active versions of Cdc42 in the dog kidney epithelial cell line MDCK grown on a two-dimensional surface leads to defective tight junction formation (typically a delay) as well as mislocalized delivery of basolateral proteins (Kroschewski et al., 1999; Rojas et al., 2001; Wells et al., 2006). Similar experiments performed with MDCK grown in three dimensions to provide a more physiological growth context have concluded that Cdc42 is required to form an apical surface through regulated trafficking of a vacuolar apical compartment (Vega-Salas et al., 1987; Martin-Belmonte et al., 2007). In this study, we describe the analysis of Caco-2, a human intestinal epithelial cell line, which, when grown in a three-dimensional matrix, generates polarized cysts with a single central lumen. We show that Cdc42 is not required for the formation of an apical surface, but instead is required to position the apical surface with respect to the growing three-dimensional structure. Our results indicate that Cdc42 regulates apical surface positioning by controlling spindle orientation during cell division.
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Results and discussion |
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TopAbstractIntroductionResults and discussionMaterials and methodsReferences |
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Cdc42 depletion inhibits Caco-2 morphogenesis
To determine the role of Cdc42 in cyst development, Caco-2 cells were transfected with nonspecific or Cdc42-specific siRNAs 1 d before plating in Matrigel (Fig. 2 B).
Treatment with CTX 6 d later results in the swelling of a single central lumen in control structures, whereas 50% of Cdc42 siRNA–transfected structures appear abnormal (Fig. 2 A and Video 4, available at http://www.jcb.org/cgi/content/full/jcb.200807121/DC1). Immunofluorescence reveals that depletion of Cdc42 results in cysts containing multiple lumens (Fig. 2, C–E). Interestingly, the surface of each lumen within the three-dimensional structure is positive for the apical marker aPKC (Fig. 2 D) and the tight junction protein ZO-1 (Fig. 2 E). These data suggest that Cdc42 is not required for the formation of apical–basal polarity and tight junctions during Caco-2 morphogenesis but rather for the correct positioning of the apical surface with respect to the growing structure.
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Cdc42 is required for mitotic spindle orientation
Based on this analysis, a consequence of Cdc42 depletion could be disruption of spindle orientation. To examine this, Caco-2 cells were transfected with Cdc42 siRNA and grown in three dimensions. 3 d later (4 d after transfection), structures were examined for orientation of mitotic spindles (calculated as described in Fig. 4 A).
Depletion of Cdc42 has a dramatic effect on spindle orientation. In control cysts, the majority of spindles are oriented perpendicular to the centroid of the cyst (mean angle = 72.3 ± 3.9°; Fig. 4, B and C [top]). However, after Cdc42 depletion, spindle orientation is randomized (mean angle = 41.2 ± 5.2° and 41.8 ± 5.7° for duplex 2 and duplex 4, respectively; Fig. 4, B and C [bottom]), with some spindles oriented so as to produce a daughter cell in the middle of the structure (Fig. 4 D).
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Asymmetric abscission ensures correct positioning of apical surfaces at the center of the cyst
The analysis of MDCK in two-dimensional and mouse intestinal epithelial cells in vivo has revealed that invagination of the cleavage furrow is asymmetric, proceeding basal to apical such that abscission occurs at the most apical point between two daughter cells (Reinsch and Karsenti, 1994; Fleming et al., 2007). This, in combination with mitotic spindle orientation, would explain the persistence of apical surfaces at the center of growing Caco-2 structures (Fig. 3 B). To examine the abscission site in Caco-2 cells, the cytokinesis midbody was visualized with a tubulin antibody. As seen in Fig. 5 A (top), at the end of the first cell division, the apical marker aPKC is associated with the midbody at the center of the interface between the two emerging daughter cells.
This strongly supports the idea that the apical surface is laid down during cytokinesis, although in the case of the first cell division, abscission appears to be symmetric. In multicellular structures (Fig. 5, A [middle] and B), 91% of midbodies are located in the center of the developing cyst, suggesting that after the first cell division, all subsequent abscissions occur asymmetrically and close to the existing apical membrane (i.e., in the center of the growing structure). In Cdc42-depleted Caco-2, <40% of midbodies are located centrally, reflecting the numerous noncentrally located apical surfaces (Fig. 5, A [bottom] and B). We conclude that the loss of Cdc42 results in spindle misorientation, leading to inappropriately placed abscission sites. Because the abscission site establishes the apical surface (Fig. 5 A, midbody position), loss of Cdc42 results in the formation of multiple lumens.
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A striking observation is that Caco-2 cells display a distinct apical membrane patch as early as the two-cell stage. This appears to be linked to cytokinesis because the apical marker aPKC associates with the midbody before abscission occurs. Apical surfaces are maintained at the center of the growing Caco-2 structure during subsequent cell divisions through a combination of (a) orientation of the mitotic spindle to generate radial cleavage and (b) asymmetric positioning of the midbody to generate apical abscission (Fig. S1 A, available at http://www.jcb.org/cgi/content/full/jcb.200807121/DC1). Oriented cell division coupled to apical abscission provides a mechanism for maintaining the structural integrity of an epithelial barrier in tissues undergoing continuous proliferation such as the intestine (Reinsch and Karsenti, 1994; Fleming et al., 2007).
Cdc42 depletion in MDCK cells leads to an accumulation of intracellular vesicles containing apical proteins, resulting in intracellular lumens, as well as cells in the middle of the cyst that are eventually cleared by apoptosis, resulting in intercellular lumens (Martin-Belmonte et al., 2007). We find no evidence for cell death after depleting Cdc42 in Caco-2; instead, multiple intercellular lumens are formed, each of which appears to be correctly polarized as judged by aPKC and tight junction localization. Because these ectopic lumens expand through polarized fluid secretion, this provides further evidence for appropriate apical–basal polarity. Further analysis reveals that Cdc42 depletion causes spindle misorientation, leading to disruption of cleavage furrow orientation and mislocalization of the midbody during cytokinesis. Because the apical surface is established at the site of abscission, Cdc42 depletion results in noncentrally located apical surfaces to generate ectopic lumens (Fig. S1 B). Cdc42 has been reported to control spindle orientation in the early C. elegans embryo and in mouse oocytes, and this is linked to its association with Par6 (Gotta et al., 2001; Na and Zernicka-Goetz, 2006), but other potential Cdc42 targets have also been linked to spindle orientation, including LIM kinase and phosphatidylinositol 3-kinase (Toyoshima et al., 2007; Kaji et al., 2008). Finally, it is interesting to note that the loss of asymmetric abscission (Fig. S1 C) could in itself lead to an inappropriately positioned apical surface. The mechanisms controlling apical midbody positioning are not well understood. Recent work on zygotic cell division in C. elegans has implicated septins and anillin (Maddox et al., 2007), and interestingly, the former has been linked to Cdc42 through the Borg family, and the latter is a target of Rho (Piekny and Glotzer, 2008). We are currently using live cell imaging to characterize in more detail the specific roles of Cd42 in this morphogenetic process.
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Materials and methods |
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TopAbstractIntroductionResults and discussionMaterials and methodsReferences |
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-tubulin (clone DM1A; Sigma-Aldrich), rat anti–E-cadherin (clone ECCD-2; Invitrogen), rabbit polyclonal PKC
(C-20; Santa Cruz Biotechnology, Inc.), ZO-1 (Invitrogen), and CFTR (NBD-R; provided by A.P. Naren, University of Tennessee, Knoxville, TN). The 5 monoclonal antibody to Na+/K+-ATPase developed by D.M. Fambrough was obtained from the Developmental Studies Hybridoma Bank and maintained by the University of Iowa. Alexa Fluor 488 and 568 secondary antibodies, rhodamine-conjugated phalloidin, and ProLong gold antifade with DAPI were obtained from Invitrogen. HRP-conjugated secondary antibodies were obtained from Dako, and DRAQ5 and 8-Cpt–2'-O-Me-cAMP sodium salt were obtained from Axxora LLC. N(6)-benzoyl-cAMP sodium salt was obtained from EMD, and other chemicals were obtained from Sigma-Aldrich.
Cell culture
Caco-2 cells were cultured in Dulbecco's modified Eagle's medium supplemented with 10% fetal calf serum and penicillin–streptomycin (100 IU/ml and 100 mg/ml, respectively) at 37°C in 5% CO2. To produce cysts, Caco-2 cells were plated either on top of matrix (for time lapse) or embedded in matrix (for immunofluorescence). For on-top cultures, cells were trypsinized and resuspended (104 cells/ml) in media plus 2% Matrigel (BD). 400 µl of suspension was plated in each well of an 8-well chamber slide (BD) precoated with 30 µl of Matrigel. For embedded cultures, cells were trypsinized and mixed with Hepes (final concentration of 0.02 M), collagen I (final concentration of 1 mg/ml; Trevigen), and Matrigel (final concentration of 40%) to 6 x 104 cells/ml. Approximately 100 µl was plated in each well of an 8-well chamber slide, allowed to solidify for 30 min, and overlayed with 400 µl of media.
Microscopy
Immunofluorescence of embedded Caco-2 cysts was performed as described previously for MCF10A cysts (Debnath et al., 2003) with the following modifications. Before blocking, Caco-2 chambers were rinsed with PBS and treated with 100 µl of 50 U/ml collagenase-1 (Sigma-Aldrich) in PBS for 15 min at room temperature. After incubation with fluorescence-conjugated secondary antibodies, DNA was stained with a 1:300 dilution of DRAQ5 and mounted in ProLong gold antifade. Confocal microscopy was performed at room temperature on a microscope (TCS SP2 AOBS; Leica) using a plan Apo 20x 0.7 NA dry differential interference contrast C objective (HC; Leica) and 2.29x zoom or on a microscope (TCS SP2; Leica) using a plan Apo 63x 1.32–0.6 oil CS objective (HCX; Leica) and 2 or 4x zoom. Images were collected with confocal software (Leica). Scale bars were added, and images were processed using Volocity (PerkinElmer). Video 1 was generated with Amira 4 (Visage Imaging). For time-lapse video microscopy, Caco-2 cysts were grown on top, treated as indicated in the text, and imaged at 37°C with a plan Neofluar 10x 0.3 NA Ph1 objective (EC; Carl Zeiss, Inc.) on a microscope (Axiovert 200; Carl Zeiss, Inc.) equipped with a motorized stage and a camera (Orca-ER-1394; Hamamatsu Photonics) controlled by Axiovision software (Carl Zeiss, Inc.). Images of two fields per well were taken every 5 min for the indicated time period. Annotations (time stamp and scale bar) were added using Axiovision software, exported as tiff files, and assembled into videos with MetaMorph (MDS Analytical Technologies).
Measurement of spindle angle
To measure spindle angles (see Fig. 4 A for schematic), confocal images of metaphase cells in the middle region of the cysts were collected, and the centroid of the cyst (Fig. 4 A, dark blue circle) and center of the spindle axis (Fig. 4 A, pink circles) were drawn using ImageJ (National Institutes of Health). The angle (Fig. 4 A, red) between the spindle axis (Fig. 4 A, black lines) and the line connecting the centroid of the cyst and the center of the spindle (Fig. 4 A, dashed lines) was analyzed. When both spindle poles were not in one z section, three z sections including each spindle pole were taken and merged to draw a line of spindle axis.
RNAi
To deplete Cdc42, a SMARTpool (a mixture of four siRNA duplexes) and individual siRNA duplexes were purchased from Thermo Fisher Scientific. For siRNA transfections, 0.5 x 105 Caco-2 cells were plated into a well of a 6-well plate, and the next day 100 pmol of siRNA duplex was transfected using Dharmafect 1 (Thermo Fisher Scientific) according to the manufacturer's specifications. Under these conditions, 70–90% of transfection efficiency was achieved as judged by siGloGreen control (Thermo Fisher Scientific). To analyze the knockdown efficiency, cells were replated onto 6-cm plates 24 h after transfection and harvested for Western blotting on the day indicated. For three-dimensional cultures, cells were plated in matrix 24 h after transfection and analyzed as indicated.
Western blotting
Cells were washed with cold PBS and lysed in radio immunoprecipitation assay buffer (50 mM Tris-HCl, pH 8, 150 mM NaCl, 1% NP-40, 0.5% sodium deoxycholate, and 0.1% SDS). Cell debris was removed by centrifugation at 14,000 rpm for 10 min at 4°C. SDS sample buffer was added to equal amounts of lysate, resolved by SDS-PAGE, blotted onto nitrocellulose membranes, and analyzed with the antibodies indicated in the text.
Online supplemental material
Fig. S1 schematically depicts Caco-2 three-dimensional morphogenesis and the effects of Cdc42 depletion. Video 1 shows a three-dimensional reconstruction of a Caco-2 cyst. Video 2 shows a Caco-2 cyst treated with CTX. Video 3 is similar to Video 2, except it shows prolonged treatment with CTX at a lower magnification. Video 4 shows siRNA Cdc42–transfected Caco-2 cysts treated with CTX. Video 5 shows a three-dimensional reconstruction of a two-cell stage Caco-2 structure stained for DNA, E-cadherin, and ZO-1. Online supplemental material is available at http://www.jcb.org/cgi/content/full/jcb.200807121/DC1.
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Acknowledgments |
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This work was supported by a National Institutes of Health grant (GM081435) to A. Hall, a National Cancer Institute core center grant (P30-CA 08748), and by the Alan and Sandra Gerry Metastasis Research Initiative. N. Kaji is supported by the Uehara Memorial Foundation, and J. Durgan is a Charles H. Revson Foundation Senior Fellow in Biomedical Sciences.
Submitted: 22 July 2008
Accepted: 1 October 2008
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