QUICK SEARCH:   [advanced] Author: Keyword(s):
Home     Help     Feedback     Subscriptions     Archive     Search     Table of Contents

First published online 11 March 2009
doi: 10.1242/dev.026963

This Article Summary Figures Only Full Text (PDF) Supplementary Material All Versions of this Article: dev.026963v1 136/8/1283    most recent Alert me when this article is cited Alert me if a correction is posted Services Email this article to a friend Similar articles in this journal Similar articles in PubMed Alert me to new issues of the journal Download to citation manager Citing Articles Citing Articles via HighWire Citing Articles via Google Scholar Google Scholar Articles by Webb, R. L. Articles by McCartney, B. M. Search for Related Content PubMed PubMed Citation Articles by Webb, R. L. Articles by McCartney, B. M. Social Bookmarking                         What's this?

A novel role for an APC2-Diaphanous complex in regulating actin organization in Drosophila

Department of Biological Sciences, Carnegie Mellon University, Pittsburgh, PA 15213, USA.

^* Author for correspondence (e-mail: bmccartney{at}cmu.edu)

Accepted 5 February 2009

	SUMMARY

TOP SUMMARY INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

 
The rearrangement of cytoskeletal elements is essential for many cellular processes. The tumor suppressor Adenomatous polyposis coli (APC) affects the function of microtubules and actin, but the mechanisms by which it does so are not well understood. Here we report that Drosophila syncytial embryos null for Apc2 display defects in the formation and extension of pseudocleavage furrows, which are cortical actin structures important for mitotic fidelity in early embryos. Furthermore, we show that the formin Diaphanous (DIA) functions with APC2 in this process. Colocalization of APC2 and DIA peaks during furrow extension, and localization of APC2 to furrows is DIA-dependent. Furthermore, APC2 binds DIA directly through a region of APC2 not previously shown to interact with DIA-related formins. Consistent with these results, reduction of dia enhances actin defects in Apc2 mutant embryos. Thus, an APC2-DIA complex appears crucial for actin furrow extension in the syncytial embryo. Interestingly, EB1, a microtubule +TIP and reported partner of vertebrate APC and DIA1, may not function with APC2 and DIA in furrow extension. Finally, whereas DIA-related formins are activated by Rho family GTPases, our data suggest that the APC2-DIA complex might be independent of RHOGEF2 and RHO1. Furthermore, although microtubules play a role in furrow extension, our analysis suggests that APC2 and DIA function in a novel complex that affects actin directly, rather than through an effect on microtubules.

Key words: Adenomatous polyposis coli (APC), Diaphanous, Drosophila syncytial development

	INTRODUCTION

TOP SUMMARY INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

 
Orchestrated cytoskeletal rearrangements play fundamental roles in a diverse array of cellular and developmental processes, from cytokinesis and cell migration to cell shape changes that underlie morphogenesis. The Adenomatous polyposis coli (APC) family of tumor suppressors can influence microtubules, and has been suggested to regulate actin (reviewed by Nathke, 2004). In addition, APC proteins (see Fig. 1A,B) are essential negative regulators of Wnt signaling (reviewed by Logan and Nusse, 2004). Although it is clear that disruption of APC signaling plays a key role in the initiation of colon cancer, excessive Wnt signaling alone may not explain the role of APC in tumorigenesis (reviewed by Nathke, 2004).

APC proteins may affect both microtubules and actin in a variety of ways (reviewed by Nathke, 2004). The microtubule-associated functions of APC proteins have become clearer in recent years with the identification of a role for APC in kinetochore-microtubule interactions (Green and Kaplan, 2003), and as part of a `cortical template' that directs microtubule network formation (Reilein and Nelson, 2005). Via its Armadillo repeats (Fig. 1A), APC can interact with Kinesin-associated protein 3 (KAP3) and appears to be transported along microtubules to the cortex via KIF3A/3B (Jimbo et al., 2002). The movement of APC along microtubules is enhanced in cell projections involved in migration (Mimori-Kiyosue et al., 2000; Nathke et al., 1996). In cultured cells, mammalian APC promotes microtubule stability (Kroboth et al., 2007), and in some contexts it promotes stability together with the formin DIA1 and the microtubule plus-end tracking protein (+TIP) EB1 (Wen et al., 2004). APC also affects microtubule dynamic instability independent of EB1 (Kita et al., 2006).

APC2 localizes with actin in multiple contexts in Drosophila embryos and epithelial cells (McCartney et al., 1999; Townsley and Bienz, 2000; Yu and Bienz, 1999). Such APC-actin interactions may influence Rho family GTPases, as APC has been shown to interact with the RacGEF ASEF and with IQGAP, an effector of RAC1 and CDC42 in cultured cells (Kawasaki et al., 2003; Kawasaki et al., 2000; Watanabe et al., 2004). Despite many reports of APC-cytoskeletal interactions, the specific mechanisms by which APC proteins affect the cytoskeleton are still poorly understood, particularly in coordinated cytoskeletal rearrangements.

The Drosophila syncytial blastoderm is a superb system in which to study dynamic coordinated actin and microtubule rearrangements. Early Drosophila embryogenesis is syncytial, with nuclear division occurring without cytokinesis (reviewed by Sullivan and Theurkauf, 1995). By interphase of nuclear cycle 10, most nuclei have migrated to the cortex to form the syncytial blastoderm. These nuclei undergo four rounds of roughly synchronous mitoses (cycles 10-13) before cellularization. During interphase, actin is organized into caps above each nucleus (see Fig. 1C,D) (reviewed by Schejter and Wieschaus, 1993). These caps `expand' into diffuse rings at the periphery of each nucleus during prophase. Cortical actin becomes focused into tight rings surrounding each nucleus during prophase of cycles 11-13, and the actin extends into the embryo to form pseudocleavage furrows that surround each spindle (Fig. 1E,F). Reaching their maximum depth during metaphase, and quickly retracting during anaphase and telophase, these furrows serve as physical barriers between adjacent nuclei that prevent collisions. Such collisions might otherwise result in abnormal nuclei and nuclear loss from the cortex (reviewed by Sullivan and Theurkauf, 1995). As daughter nuclei reform during telophase, actin redistributes into caps. These cytoskeletal rearrangements continue through each cortical syncytial nuclear cycle.

We previously showed that APC2 localizes with actin caps and pseudocleavage furrows during syncytial development, and that hypomorphic mutations in Drosophila Apc2 result in nuclear loss without significant defects in actin or microtubule organization (McCartney et al., 1999; McCartney et al., 2001). This led to a model whereby APC2 facilitates interactions between actin and microtubules that are important for nuclear tethering. Here we show that complete loss of APC2 results in defects in actin pseudocleavage furrow initiation and extension, with no apparent microtubule defects. Further, we demonstrate that APC2 works together with the formin Diaphanous to promote furrow extension, and we propose that this complex affects actin directly. Finally, the novel APC2-DIA complex we describe may function independently of the microtubule +TIP EB1 and RHO1 signaling.

	MATERIALS AND METHODS

TOP SUMMARY INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

 
Fly stocks
The following were used: Apc2^S (McCartney et al., 1999), Apc2^d40 and Apc2^g10 (McCartney et al., 2006), dia⁵ FRT40A (Afshar et al., 2000; Castrillon and Wasserman, 1994), dia^k07135/CyO [Bloomington Stock Center (BSC)], dia²/CyKrGFP (Castrillon and Wasserman, 1994), FRTG13 Rho1^L3 (Hacker et al., 2003), FRTG13 RhoGEF2⁰⁴²⁹¹ (Hacker and Perrimon, 1998) and wild type (WT; Oregon-R-S, BSC). The Eb1-null allele (Eb1^B13) is a deletion resulting from the imprecise excision of a local P-element (L. Lee, personal communication). FRT Eb1^B13 was a gift from P. Kolodziej (Vanderbilt University, Nashville, TN, USA). Mutant embryos maternally dia⁵ FRT40A, FRTG13 Eb1^B13, FRTG13 Rho1^L3 or FRTG13 RhoGEF2⁰⁴²⁹¹ were generated using FLP/FRT/DFS (Chou and Perrimon, 1996). During syncytial development, zygotic transcription is not significantly active. Genotypes referred to are maternal, and females were mated to WT males.

Immunolocalization and imaging
Embryo preparation
Embryos were collected for 2 hours (syncytial) or 6 hours (gastrulated) at 27°C, fixed and stained as described by McCartney et al. (McCartney et al., 1999), or were hand devitellinized. Antibodies and labels were as follows. Anti-β-tubulin (E7, 1:500, Developmental Studies Hybridoma Bank), anti-acetylated tubulin (1:350, Sigma), anti-APC2 [1:500 (McCartney et al., 1999)], anti-DIA [1:5000 (Afshar et al., 2000)] and anti-Anillin [1:1000 (Field and Alberts, 1995)]. Secondary antibodies were labeled with Alexa Fluor 488, 568 or 647 (1:1000, Invitrogen). Actin was detected using Alexa Fluor 488-phalloidin (1:500, Invitrogen). DNA was stained with DAPI (1:1000, Sigma) or propidium iodide (25 µg/ml, Invitrogen) for 30 minutes, following a 2-hour incubation with RNase A (10 mg/ml). Embryos were mounted in Aqua-Poly/Mount (Polysciences).

Image acquisition and analysis
Images were acquired with a spinning-disc confocal microscope (Solamere Technology Group) with a Yokogawa scanhead on a Zeiss Axiovert 200M using QED InVivo software. ImageJ and Adobe Photoshop were used for image analysis. z-stacks of 0.2 µm optical slices were taken from the apical surface to below the cortical nuclei/microtubules. To generate cross-sections from z-stacks, the x-y image stack was resliced in the x-z plane in ImageJ (Figs 2, 5, 7 and 8). Alternatively, cross-sectional single images of embryos were acquired (Fig. 4; see Fig. S4 in the supplementary material). Embryos were assigned to nuclear and cell cycle stage according to features of their DNA and/or microtubules.

Live imaging
Dechorionated embryos containing ZeusGFP, a microtubule marker (Morin et al., 2001), were mounted in halocarbon oil (700 series, Halocarbon Products) on PetriPERM dishes (Sigma). Images were acquired every 30 seconds.

Furrow depth analysis
The most apical actin section of the embryo was designated as the 0 µm position, and -0.8, -1.6, and -2.2 µm depths were also analyzed. This captured the entire furrow in the WT. Each slice was scored for complete and incomplete actin rings (i.e. those missing any portion of the ring) (see Fig. S1 in the supplementary material). Five embryos (200 actin rings) for each genotype were assessed. Statistics employed the binomial approximation of the normal distribution.

Spindle dynamics
We measured the pole-to-pole distance of ten spindles in three embryos for each genotype, from metaphase through anaphase B. We measured the midbodies in telophase. Two iterations of adaptive deconvolution using Autodeblur Gold CF software version X2.1.1 (Media Cybernetics) were performed on the images in Fig. 3D-E' and Fig. S2K-N (see Fig. S2 in the supplementary material).

Colocalization
We examined the localization patterns of APC2 and DIA in multiple nuclear cycle 12 WT embryos throughout the cell cycle at approximately -1.0 µm. Colocalization was defined as when pixel intensities 150 to 255 were detected in the same position in the APC2 image and the correlated DIA image using the ImageJ Colocalization plug-in (Fig. 4Ae-Fe).

Plasmid construction
N-terminal Glutathione S-transferase (GST) and Maltose-binding protein (MBP) fusions were generated by PCR, followed by subcloning of fragments encoding EB1 (amino acids 1-291), human APC^BasicEB1bd (2167-2843), human APC^Basic (2167-2674), human APC^EB1bd (2673-2843) and Drosophila APC^Basic (2135-2412) into pGEX-4T1 (GE Healthcare); APC2^N (1-490) into pGEX-4T3 (GE Healthcare); APC2^C (491-1067), DIA^N (1-506) and DIA^C484 (484-1091) into pLM1 (Pai et al., 1996); EB1 (1-291) and Chickadee (CHIC, Drosophila profilin; amino acids 1-126) into pMAL-c2x (NEB). His-DIA^C519 (pQE80, 519-1091) was provided by H. Muller (Grosshans et al., 2005).

Direct protein-protein interactions
Bound protein (10 µg) was incubated for 1 hour at 4°C with free protein (10 µg) in HKT buffer (Miles et al., 2005) or modified RIPA buffer (Wen et al., 2004) with 1 mM DTT. The amount of protein in the bead (B) lanes was four times that in the input and supernatant (S) lanes. Immunoblots probed with HRP-conjugated anti-MBP (1:10,000, NEB) or anti-DIA (1:10,000) were developed using the HRP SuperSignal West Pico Chemiluminescent Substrate Kit (Pierce).

Immunoprecipitation
WT 0-2 hour embryos (27°C) were lysed in 50 mM HEPES (pH 7.5), 115 mM KAc, 2.5 mM Mg(Ac)₂, 0.5% Nonidet P40 substitute (Sigma), 0.5 mM EDTA, 0.5 mM EGTA, 1x Complete protease inhibitor cocktail (Roche), 1x Phosphatase inhibitor cocktail 2 (Sigma). Anti-Myc (DSHB) immunoprecipitations were at 1:40 and anti-APC2 (McCartney et al., 1999) at 1:50. Complexes were precipitated with Protein G-agarose (Zymed). Western blots probed for APC2 (1:1000) or DIA (1:5000) were developed as described above.

	RESULTS

TOP SUMMARY INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

 
Complete loss of APC2 results in furrow extension defects
In our original study of APC2 function in the early embryo (McCartney et al., 2001), the alleles of Apc2 were not null; both Apc2^S and Apc2^d40 produce mutant proteins (McCartney et al., 1999; McCartney et al., 2006). Apc2^g10 is a nonsense mutation that changes amino acid 383 to a stop (Fig. 1B). No truncated protein was detected and the allele acts as a genetic null (McCartney et al., 2006). We previously showed that embryos maternally Apc2^g10 exhibit loss of cortical syncytial nuclei, and this loss was rescued by expression of P[Apc2⁺], an Apc2 cDNA driven by the endogenous promoter (McCartney et al., 2006).

To assess cytoskeletal defects in Drosophila Apc2 mutants, we examined actin and microtubules in fixed, stage-matched wild-type (WT) and mutant syncytial embryos. Metaphase Apc2^g10 embryos exhibited incomplete actin rings that were occasionally associated with apparent spindle collisions (Fig. 2A, arrow and arrowhead). We also observed incomplete actin rings in Apc2^d40 embryos (Fig. 2A, arrow). To determine whether these reflect defects in furrow extension, we examined stage-matched WT and mutant embryos in cross-section. Although furrows initiated in some Apc2^d40 and Apc2^g10 embryos, they did not extend normally (Fig. 2B, arrows). By contrast, furrow extension in Apc2^S embryos appeared largely as in WT (Fig. 2B). To quantify actin defects, we assessed actin rings as viewed from the surface at four depths, using the presence of incomplete actin rings as a measure of furrow depth (see Fig. S1 in the supplementary material). This analysis clearly demonstrated a statistically significant increase in the percentage of incomplete rings in the Apc2^g10 mutants at all depths as compared with WT (Fig. 2C) (P<0.001); this was partially rescued by one copy of P[Apc2⁺] (Fig. 2C). We observed an equally severe furrow extension defect in Apc2^d40 mutants (Fig. 2C). Apc2^S mutants exhibited a weak furrow extension defect that was apparent only at -2.2 µm (Fig. 2C). These results suggest that APC2 plays a role in the organization of actin pseudocleavage furrows, and thus has functions beyond spindle tethering (McCartney et al., 2001).

View larger version (44K): [in this window] [in a new window]   Fig. 1. Schematics of APC proteins and cytoskeletal rearrangements in the Drosophila syncytial embryo. (A) Multiple domains of mammalian APC interact with the cytoskeleton, either directly or indirectly. (B) Drosophila APC2 with relevant alleles indicated. Blue arrows, stop codons. A and B are modified with permission from McCartney et al. (McCartney et al., 2006). (C) At interphase, cortical actin is organized into apical caps above each nucleus. Centrosomes are located between each nucleus and its actin cap and nucleate microtubules. (D) Actin caps in a wild-type (WT) embryo expressing MoesinGFP, an actin marker. (E) At metaphase, actin has reorganized into rings (see surface view) that extend into actin pseudocleavage furrows (see cross-section). Centrosomes and microtubules have reorganized into the spindle. (F) Actin rings in the same embryo as in D, 6 minutes 30 seconds later. Scale bar: 10 µm.

Anaphase microtubules are important in furrow formation in the subsequent cell cycle (Riggs et al., 2007). We examined Apc2 mutant microtubule organization and dynamics during cycle 12 anaphase. Spindles in Apc2 mutants did not exhibit morphological defects (see Fig. S2A-J in the supplementary material), and exhibited the same dynamic behavior as WT (Fig. 3C). Furthermore, non-kinetochore microtubules and astral microtubules in Apc2 mutants appeared to have the same density and organization as in WT (Fig. 3D-F'; see Fig. S2K-L' in the supplementary material), as did interphase microtubule arrays (see Fig. S2M,N in the supplementary material). Finally, we analyzed WT and Apc2^g10 astral microtubules in cycles 9 and 10 when asters are robust, and observed no significant differences in microtubule density, in the distribution of microtubules around the astral center, or in the average maximum length of microtubules (Fig. 3G-H'; see Fig. S3 in the supplementary material). The lack of stabilized microtubules in the syncytial embryo, coupled with the lack of any discernable defects in Apc2 mutant microtubules, suggest that APC2 might affect furrow extension directly through actin.

diaphanous mutant embryos exhibit defects in furrow extension
To understand how loss of APC2 affects actin organization, we asked what other proteins function with APC2 in this process. Formins nucleate and elongate unbranched actin filaments (reviewed by Goode and Eck, 2007), and, consistent with this function, the Drosophila formin Diaphanous (DIA) influences actin furrow assembly in the syncytial embryo and during cytokinesis (Afshar et al., 2000; Castrillon and Wasserman, 1994). Interestingly, mouse DIA1 (also known as DIAP1) is reported to function with APC to stabilize microtubules in migrating cultured cells (Wen et al., 2004). To further explore the role of DIA in pseudocleavage furrow formation, and assess the potential similarities with Apc2 mutants, we examined the dia-null (dia⁵) phenotype in more detail. In some cases, most actin remained in caps during metaphase in dia⁵ mutants (Fig. 2F,F'), as previously reported (Afshar et al., 2000), but more frequently actin was located in weak rings (Fig. 2G,G'), similar to those of Apc2 mutants (Fig. 2E,E'). Furrow extension was significantly impaired in all dia⁵ mutants (Fig. 2F'',G'').

View larger version (91K): [in this window] [in a new window]   Fig. 2. Apc2 mutants exhibit defects in actin rings and furrow extension; dia5 mutants exhibit actin defects similar to those of Apc2 mutants. (A) Apical views of cycle 12 metaphase Drosophila embryos. Apc2d40 and Apc2g10 embryos display incomplete actin rings (arrows) that are occasionally associated with spindle collisions (arrowhead). A surface (0 µm) view is shown. (B) Cross-sectional views of metaphase actin show that Apc2S furrows appear largely WT, whereas furrow extension in Apc2d40 andApc2g10 mutants is grossly defective (yellow arrows). (C) Quantification of furrow extension. The percentage of incomplete actin rings at four depths for five embryos of each genotype is shown. The increase in incomplete actin rings in Apc2g10 embryos as compared with WT is significant at all depths. (D-G'') Apical (D-G), subapical (D'-G') and cross-sectional (D''-G'') views of actin in cycle 12 metaphase WT (D-D''), Apc2g10 (E-E'') and dia5 (F-G'') embryos. Defects in dia5 embryos range from actin primarily in caps during metaphase (F,F') to embryos with incomplete actin rings (G,G', arrowheads) that are similar to, but more severe than, those in Apc2g10 (E,E', arrowheads). Arrows in F'',G'' indicate effective furrow extension Scale bars: 10 µm.

The distinct temporal pattern of DIA and APC2 colocalization suggests that APC2 localization to the furrow could be DIA-dependent. In dia-null embryos, APC2 localized to actin caps during interphase and early prophase as in WT (Fig. 5A,B and data not shown). However, APC2 failed to localize with actin in the partial metaphase rings in dia⁵ mutants (Fig. 5Fa,b, arrows), and remained in the residual caps (data not shown). This trend continued through anaphase (Fig. 5Ha,b, arrows). By contrast, Anillin (Scraps - FlyBase) localized to all remaining cortical actin structures in dia mutants (Fig. 5Fc,Hc, arrows), suggesting that the loss of APC2 localization is a specific consequence of the loss of DIA. During telophase, APC2 was located at the poles of actin rings (Fig. 5Ja,b arrows) and in reforming actin caps (data not shown). The dependence of APC2 on DIA specifically when rings and furrows are prominent largely parallels the timing of colocalization between APC2 and DIA in WT embryos (Fig. 4), and supports the hypothesis that APC2 and DIA function together specifically during actin furrow extension.

View larger version (88K): [in this window] [in a new window]   Fig. 3. Syncytial embryos do not contain acetylated microtubules and Apc2 mutants have no visible microtubule defects. (A-B'') Staining for tubulin (A,B, red in merge) versus acetylated tubulin (A',B', green in merge) in gastrulated (A-A'') and syncytial (B-B'') Drosophila embryos. Unlike the acetylated microtubules in gastrulated embryos (A'), anaphase microtubules in syncytial embryos are not acetylated (B'). Overexposure (insets) reveals weak staining for acetylated microtubules at spindle poles (arrow) in syncytial embryos. (C) Pole-pole distance measurements in live cycle-12 embryos; n=30 for each. (D-E') Anaphase microtubules in WT (D,D') and Apc2g10 (E,E') cycle-12 embryos have similar densities and organization. (F,F') Schematics indicating the plane of section in D-E'. (G-H') Three-dimensional volume-rendered views of deconvolved cycle 9 anaphase asters reveals qualitatively similar astral microtubule organization in WT (G,G') and Apc2g10 (H,H') embryos. Arrows in G and H indicate the asters that are shown at high magnification in G' and H'. Scale bars: 10 µm.

Reduction of dia enhances the actin defects in Apc2 mutant embryos
We predicted that if APC2 and DIA function together during furrow extension, a 50% reduction in the dose of dia in Apc2^g10 embryos would enhance the Apc2^g10 phenotype. We reduced the dose of dia using two different alleles: dia², a deletion and reported null allele (Afshar et al., 2000), and dia^k07135, a P-element insertion in the 5'UTR (Berkeley Drosophila Genome Project). Because both alleles similarly affected the Apc2 phenotype, we report the findings for dia^k07135 (dia^k) only. Reduction of dia enhanced the Apc2^g10 phenotype in two ways. The first conspicuous difference between metaphase Apc2^g10, dia^k/CyO and dia^k/CyO; Apc2^g10 (Fig. 6B-D) embryos was at the apical surface, where some actin remained cap-like in dia^k/CyO; Apc2^g10 embryos (Fig. 6D, arrow), reminiscent of dia⁵ mutants (Fig. 2F,G). This metaphase cap-like actin is a striking enhancement; cap-like actin was not observed in Apc2^g10 mutants or dia^k heterozygotes (Fig. 6B,C). Second, we evaluated how reduction of dia affects Apc2^g10 furrow extension. We did not score rings at 0 µm for dia^k/CyO; Apc2^g10 embryos because the cap-like actin obscured the actin rings. Surprisingly, dia^k heterozygotes exhibited furrow extension defects similar in magnitude to those of Apc2^g10 at -1.6 µm and at -2.2 µm (data not shown), suggesting that DIA is limiting for furrow extension. Therefore, we focused on -0.8 µm where both Apc2^g10 and dia^k heterozygotes exhibited only weak defects (Fig. 6E). A 50% reduction in the dose of maternal dia in Apc2^g10 resulted in a significant increase in incomplete rings (47%) (Fig. 6E), as compared with either Apc2^g10 or dia^k/CyO alone (5-10%; P<0.001) (Fig. 6E). Together, these data demonstrate a dose-dependent genetic interaction between Apc2 and dia, suggesting that APC2 and DIA function in a common pathway to promote furrow extension and the dissolution of actin caps.

APC2 directly binds DIA
Previous work demonstrated that a complex including mouse DIA1, APC and EB1 influences microtubule stability in cultured cells (Wen et al., 2004). There, the C-terminus of mouse DIA1 (FH1 and FH2 domains) binds directly to the basic domain of APC and to the N-terminal domain of EB1, while the EB1-binding domain (EB1^bd) of APC binds to the C-terminus of EB1. These pairwise interactions led Wen et al. (Wen et al., 2004) to propose the formation of a ternary complex. Unlike mouse APC, Drosophila APC2 contains neither the basic domain shown to interact with DIA, nor the EB1^bd (Fig. 1B).

View larger version (95K): [in this window] [in a new window]   Fig. 4. APC2 and DIA proteins colocalize together and with actin in WT embryos. (Aa-Fe) APC2 (Ab-Fb) and DIA (Ac-Fc) colocalize with actin (Aa-Fa) throughout the cell cycle in WT cycle-12 Drosophila embryos. Colocalization of APC2 and DIA (yellow in Ad-Fd and white in Ae-Fe) is not uniform throughout the cell cycle, but peaks during prometaphase (Cd,Ce) and metaphase (Dd,De). (G) Metaphase; in cross-section APC2 (green) and DIA (red) colocalize with actin (blue) as the furrows extend. DIA is enriched at the furrow tip (arrow). Scale bars: 10 µm.

To determine whether APC2 and DIA form a complex in vivo, we immunoprecipitated APC2 from 0-2 hour WT embryos and probed the blots with an anti-DIA antibody. DIA co-immunoprecipitated with APC2, but not with control antibody (Myc) or beads alone (Fig. 6G and data not shown). The results of these biochemical assays, together with our phenotypic, protein localization and genetic interaction data, strongly support a model in which APC2 and DIA function together to extend actin furrows during cortical syncytial mitoses.

An APC2-DIA complex may function independently of EB1 in furrow extension
In mouse, EB1 is reported to function with DIA1 and APC1 to promote microtubule stability (Wen et al., 2004). We examined whether Drosophila EB1 plays a role in furrow extension, first by asking whether Eb1 mutants exhibit actin defects similar to those of Apc2 and dia mutants. In contrast to Apc2^g10 or dia⁵ mutants, maternal Eb1^B13 (null) embryos did not have incomplete actin rings (Fig. 7A,B) and exhibited partially extended furrows (Fig. 7C, arrows); the average percentage of incomplete actin rings was similar to that of WT at 0, -0.8 and -1.6 µm (data not shown). At -2.2 µm, 40% of the rings were incomplete (data not shown), compared with 92% for Apc2^g10 (Fig. 2C). Approximately 25% of Eb1^B13 embryos had actin caps during metaphase, similar to dia⁵ mutants; however, unlike dia⁵ mutants, these caps were associated with, and might be the result of, severe spindle disruptions (data not shown). Eb1 mutants also exhibited a wide array of spindle morphologies (Fig. 7A',B'), as predicted from studies in cultured Drosophila S2 cells and in syncytial embryos injected with anti-EB1 antibodies (Rogers et al., 2002). This might account for the higher frequency of nuclear loss in Eb1 mutants as compared with Apc2 or dia mutants. Furthermore, 75% of Eb1^B13 embryos exhibited disordered `mats' of actin associated with regions of significant nuclear loss (Fig. 7A,B, arrows). These actin organization defects were not observed in Apc2^g10 or dia⁵ mutants.

To further test the model that EB1 plays a role with the APC2-DIA complex during furrow extension, we reduced the dose of Eb1 in Apc2^g10 embryos. We predicted that if EB1 functions with APC2-DIA, reduction of Eb1, like the reduction of dia (Fig. 6A-E), would result in the presence of cap-like actin during metaphase, and in a more severe furrow extension defect. Unlike dia^k/CyO; Apc2^g10 embryos (Fig. 6D), apical actin appeared WT in Eb1^B13/CyO; Apc2^g10 (Fig. 7G) embryos. Furthermore, there was no significant increase in the percentage of incomplete actin rings (Fig. 7H).

View larger version (47K): [in this window] [in a new window]   Fig. 5. DIA is required for normal APC2 localization, but APC2 is not required for DIA localization. (Aa-Jc) Stage-matched cycle-12 WT (A,C,E,G,I) and dia5 (B,D,F,H,J) Drosophila embryos showing the localization of actin (Aa-Ja), APC2 (Ab-Jb) and Anillin (Ac-Jc). APC2 (Fb,Hb, arrow) fails to localize to actin rings (Fa,Ha, arrow) during metaphase and anaphase in dia5 mutant embryos, whereas Anillin continues to colocalize with actin (Fc,Hc, arrow). During telophase, APC2 localizes to remnant actin rings and reforming caps in dia5 embryos (Ja,Jb, arrow). (K,L) In WT (K) and Apc2g10 (L) cycle-12 metaphase embryos, DIA localizes to actin rings. (K',L') In cross-section (at the yellow lines in K,L), DIA (green) is enriched at the furrow tips in Apc2g10 embryos (L', arrow) as in WT (K', arrow). Scale bars: 10 µm.

Rho1 and RhoGEF2 mutant phenotypes are distinct from those of Apc2 and dia
Our data support a model in which an APC2-DIA complex functions in the development of actin furrows during cortical syncytial mitoses. Because RHO activates DIA-related formins (DRFs) (reviewed by Goode and Eck, 2007), we predicted that APC2-DIA functions downstream of RHO. To test this hypothesis, we examined the actin phenotypes of embryos maternally mutant for a hypomorphic allele of Rho1 [Rho1^L3 (Padash Barmchi et al., 2005)] and a null allele of RhoGEF2 [RhoGEF2⁰⁴²⁹¹ (Hacker and Perrimon, 1998)]. The syncytial actin defects associated with these two mutants were similar (Fig. 8D,E), but those of RhoGEF2 were more severe, consistent with the fact that RhoGEF2⁰⁴²⁹¹ is a null. If DIA is a direct downstream effector of RHO1 signaling during syncytial actin rearrangements, we predicted that the RhoGEF2 and Rho1 mutant phenotypes would include the Apc2 and dia mutant phenotypes. Contrary to expectation, the actin defects in RhoGEF2 and Rho1 mutants were distinct from those of Apc2 and dia. Rho1 (Fig. 8D) and RhoGEF2 (Fig. 8E) mutant rings exhibited areas of decreased actin (arrows) and areas of excessive actin accumulation (arrowheads) that appeared gauzy (Fig. 8D, inset) and sometimes included protruding actin `bulbs' (Fig. 8E, inset). We did not observe such actin defects in WT, Apc2 or dia mutants (Fig. 8A-C, insets). In addition, we never observed actin remaining in apical caps during metaphase in Rho1 or RhoGEF2 mutants (data not shown) as we saw in dia⁵ and dia^k/CyO; Apc2^g10 mutants (Fig. 2F,G; Fig. 6D). Finally, although the actin furrows in RhoGEF2 and Rho1 mutants are not WT, they do not have the extension defects exhibited by Apc2 and dia mutants (Fig. 8F). Similar to the surface views, RhoGEF2 and Rho1 mutant furrows in cross-section often appeared thickened (Fig. 8F, arrows), consistent with areas of excessive actin accumulation. Furthermore, both DIA and APC2 localized to actin in RhoGEF2 mutants (Fig. 8G-G''), suggesting that the actin associations of DIA and APC2 are not disrupted when RHO1 signaling is disrupted. The distinct mutant phenotypes of RhoGEF2 and Rho1 mutants suggest that APC2 and DIA are not in a simple linear pathway downstream of RHOGEF2 and RHO1.

	DISCUSSION

TOP SUMMARY INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

 
Cytoskeletal functions of APC2
APC family proteins have many well-documented effects on the microtubule cytoskeleton, whereas APC functions with actin are much less well understood. The Drosophila syncytial embryo is an excellent in vivo system in which to study the role of APC2 and its partners in organizing the cytoskeleton. We previously demonstrated that Drosophila APC2 localizes to actin in syncytial embryos, and suggested a role for APC2 in tethering cortical microtubules to actin (McCartney et al., 2001).

View larger version (51K): [in this window] [in a new window]   Fig. 6. Apc2 and dia genetically interact, and APC2 and DIA bind directly. (A-D) Actin in cycle-12 metaphase Drosophila embryos at 0 µm. In comparison to WT (A), Apc2g10 (B) and diak/CyO (C) embryos, diak/CyO; Apc2g10 (D) embryos have increased cap-like actin (arrow). Scale bar: 10 µm. (E) Quantification of furrow extension at -0.8 µm reveals enhancement of the Apc2g10 phenotype with reduction of dia. diak is diak07135. (F) His-DIAC519 binds directly to APC2C and to Chickadee, EB1, human APC1Basic and Drosophila APC1Basic (positive controls) in RIPA buffer. (G) DIA co-immunoprecipitated with APC2, but not with Myc (negative control) from 0-2 hour embryo lysates. (H) Schematic summary of APC2 and DIA constructs and interactions. B, bead; S, supernatant.

S

An APC2-Diaphanous complex
We demonstrate a novel role for an APC2-DIA complex in the organization of the actin cytoskeleton. Formins such as DIA are best known for their ability to nucleate unbranched actin filaments and accelerate filament elongation (reviewed by Goode and Eck, 2007). Drosophila DIA functions in actin-based furrow assembly during cellularization and conventional cytokinesis (Afshar et al., 2000; Castrillon and Wasserman, 1994; Padash Barmchi et al., 2005). dia mutant syncytial embryos have defects in the initiation and elongation of actin furrows, consistent with DIA subcellular localization and known roles for formins (Figs 2 and 4) (Afshar et al., 2000). We show that APC2 and DIA colocalize together and with actin specifically at times when furrows are elongating (Fig. 4). The fact that APC2 and DIA bind directly in vitro (Fig. 6), but their colocalization is cell cycle-dependent, suggests that the interaction is regulated in vivo.

The simplest model for the function of an APC2-DIA complex in actin furrow formation is that DIA-dependent nucleation and elongation of unbranched actin filaments is essential for furrow extension, and that APC2 promotes DIA activity (Fig. 9A). The fact that the dia-null phenotype is more severe than that of Apc2 (Fig. 2), coupled with the enhancement of the Apc2-null phenotype by a reduction of dia (Fig. 6), support the model that APC2 is not essential for, but might enhance, DIA activity. The dependence of APC2 on DIA for localization (Fig. 5) indicates that DIA may directly affect the regulation of its own activity.

One mechanism regulating the activity of formins has been extensively studied. DIA-related formins (DRFs) are autoinhibited through the binding of the N-terminal DIA inhibitory domain (DID) to the C-terminal DIA autoregulatory domain (DAD) (Fig. 6H). Binding of the GTPase-binding domain (GBD) by RHO-GTP relieves the autoinhibition and activates DRFs, which function as dimers (reviewed by Goode and Eck, 2007). Although RHO1 and RHOGEF2 have been reported to act upstream of DIA during Drosophila cellularization and embryonic morphogenesis (Grosshans et al., 2005; Homem and Peifer, 2008), other reports suggest that they are in a parallel pathway during these times (Mulinari et al., 2008; Padash Barmchi et al., 2005). The distinct actin defects in Rho1 and RhoGEF2 mutants as compared with Apc2 and dia mutants (Fig. 8) suggest that RHO1 is not the GTPase that directly activates DIA during furrow formation in the syncytial embryo. However, because Rho1-null embryos cannot be generated genetically owing to requirements during oogenesis, it is possible that there is a role for RHO1 in activating DIA independent of RHOGEF2. In addition, although we cannot rule out the activity of other GEFs and GTPases, these observations, along with those of formins in other systems (reviewed by Higgs, 2005), suggest the existence of alternative mechanisms for DRF activation.

Here we show that APC2 and DIA can bind directly to each other. Thus, APC2 could directly affect the function of DIA, perhaps by stabilizing the open conformation required for optimal DIA activity. Alternatively, APC2 could enhance the activity of DIA by binding to and recruiting other DIA-activating factors to the complex (Fig. 9A). Once DIA is activated it might dissociate from this complex, resulting in two pools of DIA. This notion is supported by our observation that DIA, but not APC2, is enriched at the furrow tip (Fig. 4G; see Fig. S4 in the supplementary material). We propose that in the absence of APC2, the efficiency of DIA activation is reduced, resulting in a decrease in the amount of unbranched actin filaments and a consequent production of shallow furrows (Fig. 9A). Consistent with this model for APC2 function, APC proteins are thought to play a scaffolding role in the Wnt regulatory `destruction complex' (reviewed by Kennell and Cadigan, 2008). Furthermore, vertebrate APC binds ASEF and IQGAP, activators of RAC and RAC/CDC42, respectively, through its N-terminal Armadillo repeats (Kawasaki et al., 2000; Watanabe et al., 2004). Thus, APC2 may promote the association of DIA with GEFs and GTPases, or with other proteins that promote the open conformation or otherwise enhance DIA activity.

View larger version (98K): [in this window] [in a new window]   Fig. 7 . EB1 may function independently of APC2-DIA. (A-B'') Apical views of actin (A,A'',B,B'') and microtubules (A',A'',B',B'') in cycle-12 metaphase Eb1B13 embryos. Arrows in A and B indicate actin mats; yellow lines indicate plane of sections in C. (C) Partial furrow extension (arrows) in Eb1B13 embryos in cross-section. Eb1B13 mutants exhibit a wide array of spindle morphologies, including apparently normal spindles (A') and severely disrupted spindles (B'). (D-G) Actin in cycle-12 metaphase embryos of the indicated genotypes. (H) Quantification of furrow extension shows that there is no significant effect of reduction of Eb1 on the Apc2g10 phenotype. (I) Free MBP-EB1 binds directly to DIAC484 and human APCEB1bd (positive control), but to neither Drosophila APC2 fragment in HKT buffer. B, bead; S, supernatant.

Taken together, the lack of post-translationally modified, stabilized microtubules in the syncytial embryo (Fig. 3A-B''), the lack of discernable microtubule defects in the Apc2 mutant (Fig. 3C-F'), and the lack of APC2 interactions with EB1 (Fig. 7), strongly suggest that the Drosophila APC2-DIA complex has a distinct cytoskeletal function from that of the mouse DIA1-APC-EB1 complex that stabilizes microtubules in cultured cells (Wen et al., 2004). In addition, the colocalization of APC2 and DIA specifically when furrows are extending during prophase and metaphase (Fig. 4), rather than during the critical period of microtubule function in anaphase, supports the model that the APC2-DIA complex primarily affects actin. It is intriguing that interactions between APC proteins and formins have been conserved, and that such complexes can affect both the actin and microtubule networks.

Building a furrow
Unlike conventional cytokinesis that uses actomyosin-based contraction to drive membrane invagination, Myosin II function is dispensable for pseudocleavage furrow formation (Royou et al., 2004). Many proteins are known to affect the dynamic organization of syncytial actin (Fig. 9B). Centrosomin, a core centrosome component, Sponge, a putative unconventional RacGEF, and Scrambled, a novel protein, all have roles in normal cap formation (Postner et al., 1992; Stevenson et al., 2001; Vaizel-Ohayon and Schejter, 1999). Cap formation and expansion require the Arp2/3 complex and its activator SCAR (Stevenson et al., 2002; Zallen et al., 2002). Well-known actin regulators such as RHO1, RHOGEF2 and Abelson (Abl tyrosine kinase) (Grevengoed et al., 2003; Grosshans et al., 2005; Padash Barmchi et al., 2005; Postner et al., 1992; Sullivan et al., 1993) may not affect furrow extension directly (Fig. 9B), but rather regulate the overall balance of actin activity. The Myosin VI protein Jaguar appears to play a specific role in furrow extension (Mermall and Miller, 1995), where it might stabilize actin filaments, as it does in the Drosophila testis (Noguchi et al., 2006).

View larger version (121K): [in this window] [in a new window]   Fig. 8. Rho1 and RhoGEF2 mutants. (A-F) Cycle-12 metaphase Drosophila embryos. Rho1 (D) and RhoGEF2 (E) mutants display areas of decreased actin (D,E, arrows), as well as areas of excessive accumulation of actin associated with rings (D,E, insets, arrowheads), which are not observed in WT (A), Apc2g10 (B) or dia5 (C) embryos. (F) Cross-sections stained for actin show defective thickened furrows in Rho1 and RhoGEF2 embryos (arrows). (G-G'') APC2 (G') and DIA (G'') localize to cortical actin (G) in a RhoGEF204291 mutant cycle-12 anaphase embryo. Scale bars: 10 µm.

View larger version (35K): [in this window] [in a new window]   Fig. 9. Model for Drosophila APC2-DIA function. (A) We propose that APC2 promotes the activity of DIA by facilitating the interaction between DIA and an activator. This interaction enhances the efficiency of actin nucleation in the pseudocleavage furrow. In the absence of APC2, DIA and its activator interact less efficiently, resulting in defective furrow extension. (B) Many proteins affect syncytial actin rearrangments (see Discussion).

Supplementary material
Supplementary material for this article is available at http://dev.biologists.org/cgi/content/full/136/8/1283/DC1

	Footnotes

 
We thank C. Ettensohn, T. Harris, J. Hildebrand, J. Minden, M. Peifer and members of the lab for insightful comments; C. Fried, T. Jarvela and K. Vasilev for constructs; J. Crowley for deconvolution expertise; C. Flynn for the MatLab program; and U. Hacker, C. Homem, D. Fox, M. Peifer, the Bloomington Stock Center and other members of the fly community for sharing reagents. This work was supported by Research Grant 5-FY05-34 from the March of Dimes Birth Defects Foundation and NIH RO1 GM073891-01A2 to B.M. Deposited in PMC for release after 12 months.

	REFERENCES

TOP SUMMARY INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

 

Afshar, K., Stuart, B. and Wasserman, S. A. (2000). Functional analysis of the Drosophila diaphanous FH protein in early embryonic development. Development 127,1887 -1897.[Abstract]
Castrillon, D. H. and Wasserman, S. A. (1994). Diaphanous is required for cytokinesis in Drosophila and shares domains of similarity with the products of the limb deformity gene. Development 120,3367 -3377.[Abstract]
Chou, T. B. and Perrimon, N. (1996). The autosomal FLP-DFS technique for generating germline mosaics in Drosophila melanogaster. Genetics 144,1673 -1679.[Abstract]
Field, C. M. and Alberts, B. M. (1995). Anillin, a contractile ring protein that cycles from the nucleus to the cell cortex. J. Cell Biol. 131,165 -178.[Abstract/Free Full Text]
Goode, B. L. and Eck, M. J. (2007). Mechanism and function of formins in the control of actin assembly. Annu. Rev. Biochem. 76,593 -627.[CrossRef][Medline]
Green, R. A. and Kaplan, K. B. (2003). Chromosome instability in colorectal tumor cells is associated with defects in microtubule plus-end attachments caused by a dominant mutation in APC. J. Cell Biol. 163,949 -961.[Abstract/Free Full Text]
Grevengoed, E. E., Fox, D. T., Gates, J. and Peifer, M. (2003). Balancing different types of actin polymerization at distinct sites: roles for Abelson kinase and Enabled. J. Cell Biol. 163,1267 -1279.[Abstract/Free Full Text]
Grosshans, J., Wenzl, C., Herz, H. M., Bartoszewski, S., Schnorrer, F., Vogt, N., Schwarz, H. and Muller, H. A. (2005). RhoGEF2 and the formin Dia control the formation of the furrow canal by directed actin assembly during Drosophila cellularisation. Development 132,1009 -1020.[Abstract/Free Full Text]
Hacker, U. and Perrimon, N. (1998). DRhoGEF2 encodes a member of the Dbl family of oncogenes and controls cell shape changes during gastrulation in Drosophila. Genes Dev. 12,274 -284.[Abstract/Free Full Text]
Hacker, U., Nystedt, S., Barmchi, M. P., Horn, C. and Wimmer, E. A. (2003). piggyBac-based insertional mutagenesis in the presence of stably integrated P elements in Drosophila. Proc. Natl. Acad. Sci. USA 100,7720 -7725.[Abstract/Free Full Text]
Hammond, J. W., Cai, D. and Verhey, K. J. (2008). Tubulin modifications and their cellular functions. Curr. Opin. Cell Biol. 20, 71-76.[CrossRef][Medline]
Higgs, H. N. (2005). Formin proteins: a domain-based approach. Trends Biochem. Sci. 30,342 -353.[CrossRef][Medline]
Homem, C. C. and Peifer, M. (2008). Diaphanous regulates myosin and adherens junctions to control cell contractility and protrusive behavior during morphogenesis. Development 135,1005 -1018.[Abstract/Free Full Text]
Jimbo, T., Kawasaki, Y., Koyama, R., Sato, R., Takada, S., Haraguchi, K. and Akiyama, T. (2002). Identification of a link between the tumour suppressor APC and the kinesin superfamily. Nat. Cell Biol. 4,323 -327.[CrossRef][Medline]
Kawasaki, Y., Senda, T., Ishidate, T., Koyama, R., Morishita, T., Iwayama, Y., Higuchi, O. and Akiyama, T. (2000). Asef, a link between the tumor suppressor APC and G-protein signaling. Science 289,1194 -1197.[Abstract/Free Full Text]
Kawasaki, Y., Sato, R. and Akiyama, T. (2003). Mutated APC and Asef are involved in the migration of colorectal tumour cells. Nat. Cell Biol. 5,211 -215.[CrossRef][Medline]
Kennell, J. and Cadigan, K. (2008). APC and B-catenin degradation. In APC Proteins (ed. I. S. Nathke and B. M. McCartney). Austin, TX: Landes Bioscience.
Kita, K., Wittmann, T., Nathke, I. S. and Waterman-Storer, C. M. (2006). Adenomatous polyposis coli on microtubule plus ends in cell extensions can promote microtubule net growth with or without EB1. Mol. Biol. Cell 17,2331 -2345.[Abstract/Free Full Text]
Kroboth, K., Newton, I. P., Kita, K., Dikovskaya, D., Zumbrunn, J., Waterman-Storer, C. M. and Nathke, I. S. (2007). Lack of adenomatous polyposis coli protein correlates with a decrease in cell migration and overall changes in microtubule stability. Mol. Biol. Cell 18,910 -918.[Abstract/Free Full Text]
Logan, C. Y. and Nusse, R. (2004). The Wnt signaling pathway in development and disease. Annu. Rev. Cell Dev. Biol. 20,781 -810.[CrossRef][Medline]
McCartney, B. M., Dierick, H. A., Kirkpatrick, C., Moline, M. M., Baas, A., Peifer, M. and Bejsovec, A. (1999). Drosophila APC2 is a cytoskeletally-associated protein that regulates wingless signaling in the embryonic epidermis. J. Cell Biol. 146,1303 -1318.[Abstract/Free Full Text]
McCartney, B. M., McEwen, D. G., Grevengoed, E., Maddox, P., Bejsovec, A. and Peifer, M. (2001). Drosophila APC2 and Armadillo participate in tethering mitotic spindles to cortical actin. Nat. Cell Biol. 3,933 -938.[CrossRef][Medline]
McCartney, B. M., Price, M. H., Webb, R. L., Hayden, M. A., Holot, L. M., Zhou, M., Bejsovec, A. and Peifer, M. (2006). Testing hypotheses for the functions of APC family proteins using null and truncation alleles in Drosophila. Development 133,2407 -2418.[Abstract/Free Full Text]
Mermall, V. and Miller, K. G. (1995). The 95F unconventional myosin is required for proper organization of the Drosophila syncytial blastoderm. J. Cell Biol. 129,1575 -1588.[Abstract/Free Full Text]
Miles, T. D., Jakovljevic, J., Horsey, E. W., Harnpicharnchai, P., Tang, L. and Woolford, J. L., Jr (2005). Ytm1, Nop7, and Erb1 form a complex necessary for maturation of yeast 66S preribosomes. Mol. Cell. Biol. 25,10419 -10432.[Abstract/Free Full Text]
Mimori-Kiyosue, Y., Shiina, N. and Tsukita, S. (2000). Adenomatous polyposis coli (APC) protein moves along microtubules and concentrates at their growing ends in epithelial cells. J. Cell Biol. 148,505 -518.[Abstract/Free Full Text]
Morin, X., Daneman, R., Zavortink, M. and Chia, W. (2001). A protein trap strategy to detect GFP-tagged proteins expressed from their endogenous loci in Drosophila. Proc. Natl. Acad. Sci. USA 98,15050 -15055.[Abstract/Free Full Text]
Mulinari, S., Padash Barmchi, M. and Hacker, U. (2008). DRhoGEF2 and diaphanous regulate contractile force during segmental groove morphogenesis in the Drosophila embryo. Mol. Biol. Cell 19,1883 -1892.[Abstract/Free Full Text]
Nathke, I. S. (2004). The adenomatous polyposis coli protein: the Achilles heel of the gut epithelium. Annu. Rev. Cell Dev. Biol. 20,337 -366.[CrossRef][Medline]
Nathke, I. S., Adams, C. L., Polakis, P., Sellin, J. H. and Nelson, W. J. (1996). The adenomatous polyposis coli tumor suppressor protein localizes to plasma membrane sites involved in active cell migration. J. Cell Biol. 134,165 -179.[Abstract/Free Full Text]
Noguchi, T., Lenartowska, M. and Miller, K. G. (2006). Myosin VI stabilizes an actin network during Drosophila spermatid individualization. Mol. Biol. Cell 17,2559 -2571.[Abstract/Free Full Text]
Padash Barmchi, M., Rogers, S. and Hacker, U. (2005). DRhoGEF2 regulates actin organization and contractility in the Drosophila blastoderm embryo. J. Cell Biol. 168,575 -585.[Abstract/Free Full Text]
Pai, L. M., Kirkpatrick, C., Blanton, J., Oda, H., Takeichi, M. and Peifer, M. (1996). Drosophila alpha-catenin and E-cadherin bind to distinct regions of Drosophila Armadillo. J. Biol. Chem. 271,32411 -32420.[Abstract/Free Full Text]
Postner, M. A., Miller, K. G. and Wieschaus, E. F. (1992). Maternal effect mutations of the sponge locus affect actin cytoskeletal rearrangements in Drosophila melanogaster embryos. J. Cell Biol. 119,1205 -1218.[Abstract/Free Full Text]
Reilein, A. and Nelson, W. J. (2005). APC is a component of an organizing template for cortical microtubule networks. Nat. Cell Biol. 7,463 -473.[CrossRef][Medline]
Riggs, B., Fasulo, B., Royou, A., Mische, S., Cao, J., Hays, T. S. and Sullivan, W. (2007). The concentration of Nuf, a Rab11 effector, at the microtubule-organizing center is cell cycle regulated, dynein-dependent, and coincides with furrow formation. Mol. Biol. Cell 18,3313 -3322.[Abstract/Free Full Text]
Rogers, S. L., Rogers, G. C., Sharp, D. J. and Vale, R. D. (2002). Drosophila EB1 is important for proper assembly, dynamics, and positioning of the mitotic spindle. J. Cell Biol. 158,873 -884.[Abstract/Free Full Text]
Royou, A., Field, C., Sisson, J. C., Sullivan, W. and Karess, R. (2004). Reassessing the role and dynamics of nonmuscle myosin II during furrow formation in early Drosophila embryos. Mol. Biol. Cell 15,838 -850.[Abstract/Free Full Text]
Schejter, E. D. and Wieschaus, E. (1993). Functional elements of the cytoskeleton in the early Drosophila embryo. Annu. Rev. Cell Biol. 9,67 -99.[CrossRef][Medline]
Stevenson, V. A., Kramer, J., Kuhn, J. and Theurkauf, W. E. (2001). Centrosomes and the Scrambled protein coordinate microtubule-independent actin reorganization. Nat. Cell Biol. 3,68 -75.[CrossRef][Medline]
Stevenson, V., Hudson, A., Cooley, L. and Theurkauf, W. E. (2002). Arp2/3-dependent pseudocleavage [correction of psuedocleavage] furrow assembly in syncytial Drosophila embryos. Curr. Biol. 12,705 -711.[CrossRef][Medline]
Sullivan, W. and Theurkauf, W. E. (1995). The cytoskeleton and morphogenesis of the early Drosophila embryo. Curr. Opin. Cell Biol. 7, 18-22.[CrossRef][Medline]
Sullivan, W., Fogarty, P. and Theurkauf, W. (1993). Mutations affecting the cytoskeletal organization of syncytial Drosophila embryos. Development 118,1245 -1254.[Abstract]
Townsley, F. M. and Bienz, M. (2000). Actin-dependent membrane association of a Drosophila epithelial APC protein and its effect on junctional Armadillo. Curr. Biol. 10,1339 -1348.[CrossRef][Medline]
Vaizel-Ohayon, D. and Schejter, E. D. (1999). Mutations in centrosomin reveal requirements for centrosomal function during early Drosophila embryogenesis. Curr. Biol. 9, 889-898.[CrossRef][Medline]
Warn, R. M., Harrison, A., Planques, V., Robert-Nicoud, N. and Wehland, J. (1990). Distribution of microtubules containing post-translationally modified alpha-tubulin during Drosophila embryogenesis. Cell Motil. Cytoskeleton 17, 34-45.[CrossRef][Medline]
Watanabe, T., Wang, S., Noritake, J., Sato, K., Fukata, M., Takefuji, M., Nakagawa, M., Izumi, N., Akiyama, T. and Kaibuchi, K. (2004). Interaction with IQGAP1 links APC to Rac1, Cdc42, and actin filaments during cell polarization and migration. Dev. Cell 7,871 -883.[CrossRef][Medline]
Wen, Y., Eng, C. H., Schmoranzer, J., Cabrera-Poch, N., Morris, E. J., Chen, M., Wallar, B. J., Alberts, A. S. and Gundersen, G. G. (2004). EB1 and APC bind to mDia to stabilize microtubules downstream of Rho and promote cell migration. Nat. Cell Biol. 6,820 -830.[CrossRef][Medline]
Wolf, N., Regan, C. L. and Fuller, M. T. (1988). Temporal and spatial pattern of differences in microtubule behaviour during Drosophila embryogenesis revealed by distribution of a tubulin isoform. Development 102,311 -324.[Abstract]
Yu, X. and Bienz, M. (1999). Ubiquitous expression of a Drosophila adenomatous polyposis coli homolog and its localization in cortical actin caps. Mech. Dev. 84, 69-73.[CrossRef][Medline]
Zallen, J. A., Cohen, Y., Hudson, A. M., Cooley, L., Wieschaus, E. and Schejter, E. D. (2002). SCAR is a primary regulator of Arp2/3-dependent morphological events in Drosophila. J. Cell Biol. 156,689 -701.[Abstract/Free Full Text]

CiteULike

Complore

Connotea

Del.icio.us

Digg

Reddit

Technorati

Twitter

This article has been cited by other articles:

				R. L. Webb, M.-N. Zhou, and B. M. McCartney A novel role for an APC2-Diaphanous complex in regulating actin organization in Drosophila J. Cell Sci., April 15, 2009; 122(8): e806 - e806. [Full Text]

This Article Summary Figures Only Full Text (PDF) Supplementary Material All Versions of this Article: dev.026963v1 136/8/1283    most recent Alert me when this article is cited Alert me if a correction is posted Services Email this article to a friend Similar articles in this journal Similar articles in PubMed Alert me to new issues of the journal Download to citation manager Citing Articles Citing Articles via HighWire Citing Articles via Google Scholar Google Scholar Articles by Webb, R. L. Articles by McCartney, B. M. Search for Related Content PubMed PubMed Citation Articles by Webb, R. L. Articles by McCartney, B. M. Social Bookmarking                         What's this?