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Clustering and Negative Feedback by Endocytosis in Planar Cell Polarity Signaling Is Modulated by Ubiquitinylation of Prickle

PLoS Genetics (2015) 11(5)
DOI: 10.1371/journal.pgen.1005259
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Abstract

The core components of the planar cell polarity (PCP) signaling system, including both transmembrane and peripheral membrane associated proteins, form asymmetric complexes that bridge apical intercellular junctions. While these can assemble in either orientation, coordinated cell polarization requires the enrichment of complexes of a given orientation at specific junctions. This might occur by both positive and negative feedback between oppositely oriented complexes, and requires the peripheral membrane associated PCP components. However, the molecular mechanisms underlying feedback are not understood. We find that the E3 ubiquitin ligase complex Cullin1(Cul1)/SkpA/Supernumerary limbs(Slimb) regulates the stability of one of the peripheral membrane components, Prickle (Pk). Excess Pk disrupts PCP feedback and prevents asymmetry. We show that Pk participates in negative feedback by mediating internalization of PCP complexes containing the transmembrane components Van Gogh (Vang) and Flamingo (Fmi), and that internalization is activated by oppositely oriented complexes within clusters. Pk also participates in positive feedback through an unknown mechanism promoting clustering. Our results therefore identify a molecular mechanism underlying generation of asymmetry in PCP signaling.

Figures

  • Fig 1. The Cul1 complex is required for hair and trichome polarity in the wing.Multiple hairs and swirling of hairs in adult wings (A, C, E) bearing cul1 (A) and skpA (C) knock-down, and cul1 null (cul1EX) mutant (E) clones. Growth of pre-hairs in knock-down clones (labeled by GFP) of cul1 (B), skpA (D), and slimb (G), and in cul1 null mutant clones (F, no RFP expression), is delayed (absent or smaller trichomes). Polarity of pre-hairs in neighboring wild type cells is also affected (white arrow for normal pre-hair direction and yellow arrows for abnormal pre-hair direction in B and G. Yellow dots in D and F indicate wild-type cells with defects in pre-hair polarity). 32~34hr APF pupal wings were stained with phalloidin to label Actin-rich trichomes (red in B, D, and G; green in F). Scale bars: 10μm. Genotypes are (A, B) y,w, hsflp/+(Y); UAS-cul1IR108558/+; actP>CD2>GAL4,UAS-GFP/+, (C, D) y,w, hsflp/+(Y); UAS-skpAIR32789/+; actP>CD2>GAL4, UAS-GFP/+, (E, F) y,w, hsflp/+(Y); FRT42D, cul1EX/FRT42D, ubiP-NLS::mRFP, (G) y,w, hsflp/+(Y); +/+; actP>CD2>GAL4,UAS-GFP/UAS-slimbIRFBst0033898.
  • Fig 2. The Cul1 complex regulates accumulation of core PCP components. Apical patterns of core PCP components bearing cul1 knock-down (RFP positive in A-C,). and mutant (D; homozygous for cul1EX, RFP negative) clones at 28hr APF. A”, B”, C”; quantification of fold differences for respective core proteins at junctions between cul1 RNAi (+) or wildtype (-) cells. ***P<0.0001; t-test. Endogenous Fmi (green in A and D) and Pk (green in C and blue in D) were labeled with antibodies and Fz::GFP,was expressed by heterologous promoters (green in B). All core components tested show enriched apical membrane staining in knock-down or mutant clones compared to surrounding wild-type cells (see also S1 Fig). Core proteins in wild-type cells near clones are misoriented, with Fz::GFP sequestered (E’) and Vang::YFP repelled (F’) in neighboring cells. Absence of Fz::GFP (E) and Vang::YFP (F) signal labels
  • Fig 3. Pk is required for post-transcriptional Cul1 complex-mediated core control. Apical patterns of Fz::GFP (green) and Fmi (blue) in pkpk-sple13/pkpksple14 pupal wings bearing cul1 knock-down clones (red, RFP) (A). cul1 knock-down clones (red, RFP) were also generated in pkpk-sple14/pksple1 (B) and pkpksple14/pkpk30 (C, D) wings. Fmi (green, B-D), PkPk (blue, B) and PKSple (blue, C and D) isoforms were labeled by antibody staining (the anti-Pk antibody recognizes both isoforms; in C’ and D’, signal was assumed to reflect PkSple since the PkPk isoform is not expressed). The presence of either single isoform enables apical core protein enrichment (compare A with B, C, and D) in cul1 knock-down clones. PKSple staining is very weak, but slightly stronger in at 32 h APF compared to 28 h APF (compare C’with D’). Orientation of PKSple staining corresponds to expected hair direction in pkpk/pkpk-sple mutant wings. D174GAL4 driven GFP::Pk (E), but not HA::pkdC (F), accumulates in cul1mutant (cul1EX) clones (mutant clones without RFP indicated in Ea and Fa) in 28hr APF wings. In A-D and F, yellow dots are indicating cul1 knock-down or mutant cells. Scale bars: 10μm. Genotypes are (A) y,w, hsflp/+; UAS-cul1IR108558,
  • Fig 4. Slimb interacts with Pk and accumulation of Slimb depends on pk. (A) Apical Myc::Slimb staining is diminished in pkpk-sple13 homozygous mutant clones (absence of RFP in A’). Yellow dots in A indicate mutant cells at the clonal border (A’). Asymmetric localization of Myc:Slimb is subtle, but can be appreciated by differential enrichment at boundaries of pkpk-sple13 clones (arrowheads; see also S3 Fig). Clonal overexpression of GFP::Pk (green, B) and GFP::Sple (green, C), but not HA::PkdC (green, D), sequesters Myc::Slimb (red); tubP-6XMyc::slimb was detected with anti-c-Myc antibodies (see S3C Fig for demonstration of antibody specificity). (B”b and C”c) magnified images of areas indicated with white squares in B and C. All samples are prepared from 26-28h APF pupae. Scale bars: 10μm. Genotypes are (A) y, w, hsflp/+(Y); FRT42D, pkpk-sple13/FRT42D, ubiP-NLS::mRFP; tubP-6XMyc::slimb/+, (B) y,w,
  • Fig 5. Pk protein level is regulated by Cul1-mediated ubiquitinylation and proteasomal degradation.
  • Fig 6. Pk-mediated apical clustering of core proteins requires Vang. Apical clustering of Fmi (red) is seen in cells clonally overexpressing GFP::Pk (green, A) and Pk (green, D) in wild-type (A) and fzmutant (fzR52/fzR52, D) but not in vangmutant (vangA3/vangstbm6, C) wing tissues (26hr APF). Apical clustering of Vang::YFP (green, B) with overexpression of Pk (red, B) is shown. Majority of GFP::Pk, or all of Pk, positive puncta are also positive for Fmi, or Vang::YFP, respectively (A, B). Scale bars: 10μm. Genotypes are (A) y,w, hsflp/+; +/+; actP>CD2>GAL4, UAS-RFP/UAS-GFP::pk, (B) y,w, hsflp/+; UASpk/; actP>CD2>GAL4, UAS-RFP/actP-vang::YFP, (C) y,w, hsflp/+; vangA3/vangstbm6; actP>CD2>GAL4, UAS-RFP/UAS-GFP::pk, (D) y,w, hsflp/+; UASpk/actP>CD2>GAL4, UAS-GFP; fzR52/fzR52.
  • Fig 7. Vang-Fmi internalization by Pk depends on Vang and Fz. (A-D) Sub-apical puncta positive for Pk, Fmi, or Vang::YFP in the same clones shown in Fig 6A–6D. Overexpression ofGFP::pk, or pk, induces Fmi, or Vang::YFP, positive puncta (A, B). Most puncta positive for Fmi (red, A) are also positive for GFP::Pk and all Pk positive puncta are also Vang::YFP positive (B) Fmi-positive puncta were not induced or co-labelled with GFP::Pk-positive puncta in the absence of vang (C). In the absence of fz, GFP::Pk-positive puncta are less frequent, yet those seen co-label with Fmi (D). Without fz, Fmi-positive puncta are less frequent or less bright with or without pk overexpression (see Fmi staining in- and outside of pk overexpressing clones in D and compare with A). (E) Vang::YFP puncta are induced by ptc-GAL4 driven pk overexpression when fmi is simultaneously knocked down, showing that Fmi is not absolutely required for Pk dependent Vang puncta formation (Pk, red; Vang::YFP, green; Fmi, blue). Clones are outlined and magnified areas are indicated by white squares. Scale bars: 10μm. Genotypes for A-D are same as those in Fig 6. Genotype for E is, UAS-Dcr2/+; ptc-GAL4/UAS-pk; actP-vang::YFP/UAS-fmiIRFBst0026022.
  • Fig 8. Endocytosis of membranous Pk and Vang.Windows were created over the wing of live 24-26h APF pupae by opening the pupal case and cuticle, and then incubated in FM4-64 solution. Apical or sub-apical puncta for GFP::Pk (green in A) and Vang::YFP (green in B) were then visualized. (A) Many GFP::Pk positive cytosolic puncta (GFP::Pk driven by ptc-GAL4) co-labeled with FM4-64. (B) In pk overexpressing clones (outlined), Vang::YFP frequently co-labeled with FM4-64. Double positive puncta for GFP::Pk, or Vang::YFP, and FM4-64 are indicated with arrowheads (see the manuscript for quantification). Scale bars: 10μm. Genotypes are (A) ptc-GAL4/+; UAS-gfp::pk, (B) actP>CD2>GAL4/y,w, hsflp; UAS-pk/+; actP-vang::YFP.

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Cho, B., Pierre-Louis, G., Sagner, A., Eaton, S., & Axelrod, J. D. (2015). Clustering and Negative Feedback by Endocytosis in Planar Cell Polarity Signaling Is Modulated by Ubiquitinylation of Prickle. PLoS Genetics, 11(5). https://doi.org/10.1371/journal.pgen.1005259

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