Animals

AB wild-type strain, nok^m520, has^m567 moe^b476, moe^b781 and moe^b882 alleles were maintained and staged as previously described (Jensen et al., 2001). The moe^b476 and moe^b781 alleles were crossed into the Rhodopsin-GFP (Xop-GFP) transgenic line (Fadool, 2003).

UV-opsin GFP transgenic fish construction

UV-opsin GFP transgenic fish were generated by cloning a 7 kb SacI fragment from a UV-opsin⁺ PAC clone, including ∼870 bases of the coding region plus 6 kb upstream, into the pG1/pESG GFP vector to generate a fusion protein that includes most of the UV opsin protein with GFP at the C-terminus. Linearized plasmid (60 ngμl) was injected into single-cell embryos; germline founders were identified by PCR.

In situ hybridization

Whole-mount and section in situ hybridizations were performed as previously described (Jensen and Westerfield, 2004). cDNAs were linearized and transcribed: crb2b XhoI, SP6; crb2a NotI, SP6; mouse ymo1 BglII, T3; mouse crb1 (Accession number BM941539) Not1, T3; mouse crb2 (Accession number BI738283) EcoRI, T7.

Morpholino knockdown

crb2a splice-blocking morpholinos were targeted to the intron (∼810 bases) between the second and third coding exons. Donor morpholino sequence was TTGCACTTCAATTACCTGTATATCC and acceptor was ACAGTTTACACCTACAGAGATCACA. Injection of donor morpholino (200 μmol/l) produced no discernable abnormality, while injection of acceptor morpholino (200 μmol/l) produced a weak moe-like phenotype in about 50% of injected embryos. Co-injection of both morpholinos (each 200 μmol/l) produced a moe-like phenotype in all injected wild-type embryos. Morpholino activity was tested by RT-PCR on RNA isolated from 60 30-hpf injected embryos. Primers used for RT-PCR were: RT, GCGGTCGTGGCAAAGTC); PCR, GGCGAGACCTGTGAAGAAGACC and CCGTTTTGACAGGGATTTGACTC. Co-injection of nok splice-blocking morpholinos (each 200 μmol/l; donor, GTTTATGACACCCACCTAGTAAAGC; acceptor, CTCCAGCTCTGAAAGTACAAACACA) produced a phenotype indistinguishable from nok mutants (not shown).

Construction and expression of fusion proteins

GST-tagged Crb^intra proteins: sequences encoding the intracellular domains of Crb proteins plus variable amounts of transmembrane domain were cloned into pGEX-4T-1 (Amersham); Crb1, Crb2a, Crb2b, Crb3a and Crb3b are 40, 42, 42, 61 and 65 amino acids, respectively. A Moe fragment (EST accession number CD750925) encoding amino acids 1-434 was cloned into pRSET-A to make His-Moe_FERM. For MBP Moe_FERM and MBP-Moe_C-terminus sequence encoding residues 59-383 and sequence encoding residues 383-772, respectively, was cloned into pMal C2X (NEB). To make His-Nok proteins, full-length Nok and a fragment encoding the first 411 amino acids (Nok-N, including the PDZ domain) were cloned into pRSET-A or -B (Invitrogen). To make GST-Nok-Int, a 468 bp internal StuI-PstI fragment of Nok encoding the predicted Band 4.1 interacting region was cloned into pGEX4T-1.

Antibody production

Polyclonal antibodies to Moe were generated by immunizing rabbits (UMASS antibody facility) and guinea pigs (Rockland Immunochemicals) with purified His-Moe_C term fusion protein (amino acids 383-772, Accession number CD750925).

Biochemical assays

Immunocytochemistry and microscopy

Zebrafish were fixed in 4% PFA, and sections (18 or 30 μm) permeabilized with 0.1% SDS for 15 minutes, washed in PBSTw, and incubated in blocking solution then with primary antibody overnight at 4°C: rabbit anti-Moe 1:1000; guinea pig anti-Moe 1:500; anti-CRB3 1:400; anti-Nok 1:400; anti-aPKCζ 1:1000; mouse anti-ZO-1 1:10; rabbit anti-GFP 1:300 (Molecular Probes); mouse anti-Rhodopsin 1:100; mouse Zn5 1:5 (ZIRC); anti-phospho-H3 1:1000 (Upstate Biotech). Sections were washed, incubated with secondary antibody [-FITC/-TRITC (Molecular Probes) 1:200, -CY5 1:100 (Jackson)] and analyzed with a Zeiss LSM 510 Meta Confocal System. Confocal images are a single scan (four to eight averaged), optical thickness ∼1 μm. Images in Fig. 2 were taken with the same settings.

Blastomere transplantations and generation of retina mosaics

Donor embryos were produced by incrossing Rhodopsin-GFP;moe^b781/+ fish. At the high stage to dome stage, ∼20-40 cells were transplanted from labeled-donor embryos into wild-type host embryos (Jensen et al., 2001). Larvae were placed in the dark for 2 hours and were fixed and sectioned (30 μm) as described above. Confocal z-stack images (∼1μ m optical thickness) were acquired every 0.38 μm. Cell volume was approximated by accumulating the area of the cell on each z-section: cell area was outlined and measured in each z-section and for each cell the area from the z-sections was summed to represent volume. Only cells completely captured in the z-stack were included in the calculations. Measurements were repeated and averaged to reduce sampling error. Donor cells were not lineage traced with rhodamine dextran for the experiments localizing panCrb and ZO-1 in GFP⁺ rods so that rhodamine could be used for antibody localization.

Identification and expression of Zebrafish crumbs orthologs

There are three vertebrate Crumbs orthologs, Crb1, Crb2 and Crb3 (den Hollander et al., 1999; van den Hurk et al., 2005; Makarova et al., 2003). In order to test our hypothesis that Moe forms a complex with Crumbs proteins, we had to clone zebrafish crumbs genes. We used sequences from the zebrafish genome project to clone crb1, crb2a, crb2b and crb3b, and found an EST for crb3a. These are the same crumbs genes recently described by Omori and Malicki (Omori and Malicki, 2006). To determine whether any of these crumbs orthologs are coexpressed in the same cells and tissues as moe, we performed in situ hybridization in embryos and eyes. At 30 hours post-fertilization (hpf), moe and crb2a were expressed in the skin, nose and epiphysis, and ubiquitously in the brain and eye; crb2b was very weak in the brain but highly expressed in the epiphysis and nose (Fig. 1A). At 7 days post-fertilization (dpf), moe and crb2a were expressed in photoreceptors, cells in the inner nuclear layer, proliferating cells in the peripheral margin, and cells in the anterior chamber (Fig. 1B); crb2b was detected in a small number of newly differentiating photoreceptors in the periphery and cells in the anterior chamber (Fig. 1B). At 3 dpf, we observed high expression of crb2b in newly differentiating photoreceptors and no expression of crb1, crb3a or crb3b in the retina (data not shown) like that observed by Omori and Malicki (Omori and Malicki, 2006). In adults, moe and crb2a were expressed in photoreceptors and cells in the inner nuclear layer (Fig. 1C).

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Fig. 1.

Expression of zebrafish crb2 genes. (A) moe and crb2a are expressed in the brain, eye and nose (arrows) at 30 hpf; crb2b is expressed in the nose (arrow) and weakly or not at all in the brain and eye. (B) moe and crb2a are expressed in photoreceptors, cells in the inner nuclear layer, progenitor cells in the periphery and cells in the anterior chamber at 7 dpf; crb2b expression is detected in a small number of newly differentiating photoreceptors near the ciliary margin (arrows) and in cells in the anterior chamber (arrowheads). (C) Zebrafish moe and crb2a are expressed in photoreceptors and cells in the inner nuclear layer in adults. (D) Mouse ymo1, crb1 and crb2 are expressed in photoreceptors and cells in the inner nuclear layer in the adult. Scale bars: 100 μm. INL, inner nuclear layer; PR, photoreceptors.

We also examined the expression of the mouse ortholog of moe, ymo1 (Drosophila yurt and zebrafish moe like 1; annotated Erythrocyte Protein Band 4.1 Like 5 in the human genome), along with crb1 and crb2 in the adult mouse retina. We found that ymo1 was expressed in the same population of cells as crb1 and crb2 and was expressed in photoreceptors and a subset of cells in the inner nuclear layer (Fig. 1D), similar to that expression previously shown by den Hollander and colleagues (den Hollander et al., 2002) and van den Hurk and colleagues (van den Hurk et al., 2005), although we did not detect crb2 expression in the retinal ganglion layer or in bipolar cells like that reported by van den Hurk and colleagues (van den Hurk et al., 2005). Coexpression in the same populations of cells of moe and crb2a/b genes in zebrafish and the orthologous genes in mouse is consistent with the idea that the genes/proteins interact.

Morpholino knockdown of crb2a phenocopies moe mutations

To test whether loss-of-function of zebrafish crumbs orthologs would phenocopy the moe mutations, we targeted knockdown of crb2a gene function, because its expression most closely resembles moe expression. Injection of crb2a splice-blocking morpholinos into one to two-cell wild-type embryos (hereafter called crb2a morphants) inhibited splicing as tested by RT-PCR (see Fig. S1A in the supplementary material) and produced a phenotype that is indistinguishable from moe mutants, including reduced brain ventricles, edema of the heart cavity and patchy retinal pigmented epithelium (see Fig. S1C,D in the supplementary material). The similarity in phenotype between crb2a morphants and moe mutants extended to loss of retinal lamination and the ectopic localization of retinal ganglion cells and rod photoreceptors (see Fig. S1E-P in the supplementary material). crb2a morphants died around 5-6 dpf, similar to moe mutants. The observation that moe and crb2a loss of function cause similar phenotypes further supports the idea that moe and crumbs genes/proteins interact. Omori and Malicki (Omori and Malicki, 2006) reported recently that the ome locus is crb2a and our ome morphant phenotype was like their ome morphants.

Localization of Moe and Crumbs proteins requires reciprocal protein function

If Moe forms a complex in vivo with Crb proteins, the proteins should show some colocalization. To examine the localization of Moe protein, we generated Moe polyclonal antibodies and showed by western blot that a protein of∼ 110 kDa was recognized by the antibody in wild type and was absent in all moe mutant alleles (Fig. 2A). The molecular weight of Moe protein is larger than predicted (∼89 kDa), suggesting that it may be modified post-translationally. To examine the localization of Crumbs proteins, we determined by western blot that the antibody raised against the intracellular domain of human CRB3 (Makarova et al., 2003) recognized the recombinant intracellular domains of all the zebrafish Crumbs proteins we identified (Fig. 2B), and thus anti-CRB3 should be considered a pan-Crb antibody in zebrafish, and hereafter is referred to as anti-panCrb.

We examined the localization of Moe and panCrb in wild-type embryos and whether their localization depends on the function of moe, nok (pals1), crb2a/ome and has (aPKCλ). We included has mutants (Horne-Badovinac et al., 2001) because its phenotype is similar to moe, ome and nok mutants and crb2a morphants. In addition, the Par complex, which includes aPKCλ, interacts with Crumbs complexes (Wodarz et al., 2000; Hurd et al., 2003; Lemmers et al., 2004; Nam and Choi, 2003), and in Drosophila, Crumbs is a target of DaPKC (Sotillos et al., 2004). In 30 hpf wild-type embryos, both Moe and panCrb were concentrated at the apical surface of the brain and retinal neuroepithelium; Moe also localized cortically in all neuroepithelial cells (Fig. 2C,D). In moe mutants, Moe was lost, and apical panCrb in the brain and retinal neuroepithelium was lost (Fig. 2E,F). In crb2a morphants, ome and nok mutants, apical Moe and panCrb were lost, although in nok mutants disorganized plaques of Moe labeling were observed near the brain midline (Fig. 2G-J,M,N). In has mutants, apical Moe and panCrb in the brain and retinal neuroepithelium were reduced and patchy compared with wild-type embryos (Fig. 2K,L). Double labeling and colocalization of Moe and panCrb is provided in Fig. S2 in the supplementary material. Both Moe and panCrb localize to the apical neuroepithelium and their localization is co-dependent, further supporting the idea that the proteins might interact.

Loss of panCrb labeling at the apical surface in moe, nok and ome mutants could be due to loss of Crb proteins; or, alternatively, Crb proteins may be present but no longer localized apically and instead are diffuse. To distinguish between these two possibilities, we performed western blot analysis of 30 hpf wild-type, moe, nok and ome mutants. In wild-type embryos, a protein of about 150 kDa was recognized by anti-panCrb antibody. The predicted molecular weight of Crb2a is about 156 kDa, and it is by far the most abundantly expressed crumbs gene at 30 hpf; thus this protein is probably Crb2a. Levels of this protein were unaffected in moe^b781 mutants (and moe^b476 deficiency, not shown), barely detectable in crb2a morphants and nok mutants, was absent in ome mutants (Fig. 2O) and moderately reduced in has mutants (data not shown). Expression of crb2a and crb2b mRNA by in situ hybridization was unaffected in crb2a morphants, moe, nok and ome mutants (data not shown). These results suggest that Moe is required either for apical localization (or retention) or for trafficking of Crumbs proteins.

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Fig. 2.

Localization of Moe and Crumbs proteins in embryonic brain and eye. (A) Western blot of wild type, moe^b476, moe^b781, moe^b882 3d larvae probed with rabbit anti-Moe. Anti-Moe recognizes a protein of approximately 110 kDa in wild-type extracts that is absent in moe mutants. The blot was reprobed with anti-α-Tubulin as a loading control. (B) Anti-CRB3 recognizes the intracellular domains of all zebrafish Crumbs proteins. Western blot of GST, GST-Crb1^intra, GST-Crb2a^intra, GST-Crb2b^intra, GST-Crb3a^intra, GST-Crb3b^intra probed with anti-CRB3 antibodies. The blot was reprobed with anti-GST as a loading control. (C-N) Moe (green) and panCrb (red) labeling in 30 hpf brain and eye in wild-type (C,D), moe^b781 (E,F), crb2a morphant (G,H), nok (I,J), has (K,L) and ome (M,N) embryos. Arrows indicate brain ventricles and eyes are outlined. High magnification of the apical ventricular surface of the brain (BVS) and eye/retinal surface (ES) are shown to the right. Scale bars: 10 μm. (O) Western blot of 30 hpf wild-type, moe^b781, crb2a morphant, nok and ome embryos probed with anti-panCrb antibodies. One-fifth of the material loaded for the panCrb Western was probed with anti-α-Tubulin to show relative loading amounts.

Localization of Moe, Crumbs proteins, Nok and aPKCλ in the retina

Because Crumbs proteins are important for retinal development, we examined whether Moe colocalizes with panCrb in the retina as well as with Nok (Pals1) and Has (aPKCλ). At 7 dpf, Moe localized to the photoreceptor layer, retinal progenitors in the periphery and cells in the anterior chamber (Fig. 3A-F), while panCrb localized to the photoreceptor layer apical to the outer limiting membrane (OLM) and the apical surface of progenitor cells in the periphery (Fig. 3A). Merging the Moe and panCrb images shows that anti-Moe and anti-panCrb strongly colocalized in newly differentiating photoreceptors (Fig. 3A, Moe+anti-panCrb, bracket) at the periphery of the photoreceptor layer. Higher magnification of Moe and panCrb colocalization in the photoreceptor layer was shown at 4 dpf, a time when most photoreceptors are forming outer segments (Fig. 3B). Moe also colocalized with Nok and aPKCλ in the photoreceptor layer and with aPKCλ in the outer plexiform layer (Fig. 3C-F). Colocalization of Moe with panCrb, Nok and aPKCλ places these proteins in a position to potentially interact.

We also examined the localization of Moe and panCrb relative to markers for photoreceptors and Müller glia, which send processes into the photoreceptor layer. Moe and Crb proteins appeared to be in all photoreceptor types examined, and Moe was in Müller processes that project into the photoreceptor layer (Fig. 4A-G). We also examined Moe and panCrb localization in the photoreceptor region relative to the OLM, a specialized adherens junction between photoreceptor cells and Müller glia and between individual Müller cells and individual photoreceptors (Williams et al., 1990). In mouse retina, Crb1 localizes just apical to OLM and deficiencies in Crb1 result in OLM defects (Mehalow et al., 2003; van de Pavert et al., 2004). The highest level of Moe labeling was basal to the OLM, as marked by anti-ZO-1, but anti-Moe labeling was also observed apical to the OLM, where panCrb labeling localizes (Fig. 4H,I).

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Fig. 3.

Localization of Moe, panCrb, Nok and aPKCλ in the retina. (A,B) Colocalization of guinea pig anti-Moe and panCrb labeling in the peripheral region in 7 dpf eye (A) and photoreceptor layer at 4 dpf (B). AC, anterior chamber; PC, proliferating cells; PR, photoreceptors. (C,D) Colocalization of guinea pig anti-Moe and anti-Nok labeling in the peripheral region in 7 dpf eye (C) and photoreceptor layer at 4 dpf (D). (E,F) Colocalization of guinea pig anti-Moe and anti-aPKCλ labeling in the peripheral region in 7 dpf eye (E) and photoreceptor layer at 4 dpf (F). Insets are magnification of boxed areas. Scale bars: 20 μm; 10 μm in insets.

Moe forms a complex with Crumbs proteins, Nok (Pals1) and Has (aPKCλ)

Because Crumbs proteins contain a predicted FERM-binding domain and Moe is a FERM protein, we sought to determine whether Moe and Crumbs proteins physically interact. We found that anti-panCrb (anti-CRB3) antibodies co-immunoprecipitated proteins recognized by anti-Moe (∼110 kD), anti-panCrb (∼150 kDa) and anti-Nok (∼80 kDa) from adult eyes (Fig. 5A). We also found that a fusion protein of Moe that includes the FERM domain (Moe_FERM) pulled down a∼ 150 kDa protein from larval lysates that was recognized by anti-panCrb antibody (Fig. 5B), further supporting the idea that Moe and Crumbs proteins form a complex. We also showed that Moe_FERM can pull down a ∼80 kDa protein recognized by anti-Nok from 3 dpf wild-type larvae and adult eyes but not from nok morphants (Fig. 5C,E). Further, we showed by western blot that this ∼80 kDa protein was absent in nok^m520 (Fig. 5D), indicating that this protein is encoded by the nok locus.

Given that Moe and aPKCλ colocalized in tissue, we also tested whether aPKCλ (Has) forms a complex with Moe. Moe_FERM pulls down a protein of about 72 kDa that was recognized by antibody to the highly related protein aPKCλ (Fig. 5F). The ∼72 kDa protein recognized by anti-aPKCλ was absent in has^m576 (Fig. 5G), suggesting that this protein is encoded by the has locus. A protein of about 52 kDa was also pulled down, but it is unclear whether this represents an isoform of aPKCλ, an aPKCλ degradation product (Coghlan et al., 2000), or another protein that crossreacts with the aPKCλ antibody that was pulled down by Moe_FERM.

Moe interacts directly with Crumbs proteins and Nok (Pals1)

To test whether Moe directly binds to Crumbs proteins, we performed in vitro GST pull-down and far western experiments using purified recombinant proteins. Immobilized His-Moe_FERM interacted with GST-Crb2a^intra, GST-Crb2b^intra and, to a lesser extent, GST-Crb1^intra (Fig. 6A). Furthermore, we showed by far western analysis that GST-Crb1^intra, GST-Crb2a^intra and GST-Crb2b^intra bind to His-Moe_FERM immobilized on nitrocellulose (Fig. 6B). Taken together, our biochemical data suggest that Moe interacts directly with Crumbs proteins.

Both Nok and Pals1 have predicted Band 4.1-binding domains consisting of several lysine residues (Kamberov et al., 2000; Wei and Malicki, 2002) and Stardust has a similar stretch of residues following the SH3 domain. We sought to determine whether Moe, a Band 4.1 protein, interacts directly with Nok (Pals1). We showed that immobilized GST-Nok-Int, containing the predicted Band 4.1-binding motif, pulled down MBP-Moe_FERM but not MBP-Moe C-terminus (Fig. 6C). We also showed in far western experiments that MBP-Moe_FERM bound to nitrocellulose-bound full-length Nok (His-Nok-FL), but not His-Nok-N, which does not contain the predicted Band 4.1-binding domain (Fig. 6D). We also showed that His-Nok-N (including the PDZ domain) directly interacted with both GST-Crb2a^intra, GST-Crb2b^intra proteins by far western (see Fig. S3 in the supplementary material). Our biochemical analyses show that Moe interacts directly with Crumbs proteins and Nok (Pals1).

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Fig. 4.

Localization of Moe and panCrb in specific retinal cell types at 5 dpf. (A) Merged guinea pig anti-Moe labeling of rod photoreceptors (in transgenic Xop-GFP fish) with rabbit anti-GFP. (B) Merged rabbit anti-panCrb labeling of GFP⁺ rod photoreceptors with GFP (in transgenic Xop-GFP fish). (C) Merged guinea pig anti-Moe labeling of UV cones with GFP (in transgenic UV-GFP fish) labeled with mouse anti-GFP. (D) Merged rabbit anti-panCrb labeling of UV cones with GFP (in transgenic UV-GFP fish) labeled with mouse anti-GFP. (E) Merged rabbit anti-Moe labeling of double cones with mouse Zpr-1 antibodies. (F) Merged rabbit anti-panCrb labeling of double cones with mouse Zpr-1 antibodies. (G) Merged guinea pig anti-Moe labeling of Müller glial cells with rabbit anti-Carbonic anhydrase II antibodies. (H) Rabbit anti-Moe, mouse anti-ZO-1, merged anti-Moe and anti-ZO-1, and merged with corresponding DIC image. (I) Rabbit anti-panCrb, mouse anti-ZO-1, merged anti-Moe and anti-ZO-1, and merged with corresponding DIC image. Scale bar: 10 μm. CB, cell bodies.

The role of Moe in photoreceptor morphogenesis

Given the important role of Crumbs proteins in photoreceptors in Drosophila, mice and humans, we sought to determine whether Moe, probably through its interaction with Crumbs proteins, plays a role in vertebrate photoreceptor morphogenesis. Because the position of photoreceptors is so abnormal in moe mutants (see Fig. S1O in the supplementary material) (Jensen et al., 2001), examination of their morphology is uninformative. To overcome this limitation, we used genetic mosaic analysis and a transgenic line that expresses GFP in rods (Fadool, 2003). When moe mutant cells are transplanted into wild-type hosts at the blastula stage, moe mutant cells are almost invariably found in their normal laminar position in the retina (Fig. 7) (Jensen et al., 2004), and so we used this strategy to examine the morphology of GFP⁺ rods that lack moe function. Wild-type rods have a stereotypical morphology: a basal synaptic terminal, a round cell body, a thin apical inner segment (IS) and a thick apical outer segment (OS) filled with rhodopsin (Fig. 7A,B,G,H).

At 6 dpf, the morphology of moe^- rods seemed largely normal, but the cells were almost 50% larger than wild-type rods (Fig. 7C-F,O). We measured the accumulated area of the OS versus the IS and cell body and found that the size increase in moe^- rods was due largely to an increase in the size of the OS (Fig. 7O). By 10 dpf the morphology of moe^- rods was markedly abnormal and the cells were about 50% larger than wild-type rods (Fig. 7I-N,P). Most often moe^- rods displayed a coiled apical structure that seemed to encompass both the IS and OS and seemed larger than the combined area of the IS and OS area of wild-type rods (Fig. 7I,K,L-N). We could not accurately measure the OS versus the IS and cell body at 10 dpf because the morphology was so distorted. We grouped transplanted moe^- rods into two groups by examining the genotype of neighboring cells; one group included moe^- rods that had few moe^- neighbors (Fig. 7I-K) and the other group moe^- rods had large numbers of moe^- neighbors (Figure L-N). Generally, moe^- rods with large numbers of moe^- neighbors were more abnormal (Fig. 7L-N) than those with mostly wild-type neighbors (Fig. 7I-K). Rhodopsin remained localized to the most distal portion of the cell (Fig. 7I-N), suggesting that apical-basal polarity is preserved. Three-dimensional movies of moe^- rods are provided (see movies 1-5 in the supplementary material).

We examined the localization of Crumbs proteins in wild type and moe^- rods in our transplant experiments. At 6 and 10 dpf, anti-panCrb labeling in the inner segment in moe^- rods did not seem different from wild-type rods (Fig. 7Q-X). Localization of ZO-1 appeared normal around moe^- rods in genetic mosaics (see Fig. S4 in the supplementary material). The observations that the apical region was expanded in moe^- rods suggest that Moe may normally act to inhibit apical size in photoreceptors. Interestingly, proper localization of Crumbs proteins to the photoreceptor IS does not appear to require Moe function, contrary to that observed in embryos (see Fig. 2).

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Fig. 5.

Moe forms a complex with Crumbs proteins, Nok (Pals1), and Has (aPKCλ). (A) Anti-panCrb (anti-CRB3) antibodies coimmunoprecipitate Moe (recognized by guinea pig anti-Moe), Crb2a/b, and Nok from adult eye. NRS, normal rabbit serum. Arrows indicate Moe, Crb2a/b, Nok protein. One asterisk indicates rabbit antibody; two asterisks indicate cross-reactivity of anti-guinea pig-HRP with rabbit antibody. (B) His-Moe_FERM, but not His-LacZ, pulls down a ∼150 kDa protein from 3 dpf larval lysates that is recognized by anti-panCrb antibodies. (C) His-Moe_FERM, but not His-LacZ, pulls down an ∼80 kDa protein from wild-type 3 dpf larval lysates, but not from nok morphant lysates, recognized by anti-Nok antibodies. (D) Anti-Nok antibodies recognize an ∼80 kDa protein in 3 dpf wild-type lysates that is absent in nok mutants and morphants in western blot. (E) His-Moe_FERM, but not His-LacZ, pulls down an ∼80 kDa protein from adult eye lysates recognized by anti-Nok antibodies. (F) His-Moe_FERM pulls down∼ 75 kDa and ∼50 kDa proteins from 3 dpf larvae lysates that are recognized by anti-PKCλ antibodies. (G) Anti-PKCλ antibodies recognize proteins of approximately 75, 57, 54 and 50 kDa in western blot of 3 dpf wild-type lysates; the 75 kDa and 50 kDa proteins are absent in lysates from has mutants (Has^-/-).

Supplementary material

Supplementary material for this article is available at http://dev.biologists.org/cgi/content/full/133/24/4849/DC1