Chien YH , Srinivasan S , Keller R , Kintner C .

R01 HD092215 NICHD NIH HHS , P30 NS072031 NINDS NIH HHS

	Figure 1 Strain, Polarized MTs, and PCP Components in the LRO (A–C) Diagrams of the vegetal (A) and dorsoposterior aspects (B and C) of the Xenopus embryo during gastrulation illustrate the development of patterns of strain in the IMZ, and the presumptive GRP, during gastrulation. See text for explanation. (D) After gastrulation, the LRO (boxed area in C, inverted and viewed from the inside) differentiates by forming flow producing cells medially (M; long motile cilia that reposition to the posterior cell edge), and flow sensing cells laterally (L; immotile short cilia that remain in a more central planar position). (E) The LWR of LRO cells at different stages are shown on a Tukey boxplot. (F) The LWR of cells in three LROs at stage 12 is plotted versus position along the M-L axis, combining data from both sides, showing the average for equivalent size bins, the 95% confidence range, and the best-fit curve (Table S2). (G and H) Polar plots summarizing MT orientation in medial (G) and lateral (H) LRO cells (Figures S2A and S2B, Table S1). (I) MT alignment within medial and lateral LRO cells, where each point represents the standard deviation from the mean for an individual cell (Table S1). (J) Plots summarizing the stable fraction of fz3-GFP at junctions oriented parallel (P) or orthogonal (O) to the A-P axis, in medial and lateral LRO cells (Table S1). (K and L) Cilia length (K) and planar positioning (L) are plotted versus cell position in the LRO at stage 18, as the average for equivalent size bins, the 95% confidence range, and the best-fit curve (Table S2). Planar positioning is measured as a distance from the geometric center (0) to the posterior cell edge (1) normalized to one. Error bars in (I) and (J) indicate the mean ± SD. Full statistics and sample size for these data are provided in Table S1.
	Figure 2 Ciliation Defects in Explants that Lack Strain (A–E) Dorsal explants (dotted line, A) cultured on FN (B) or placed together into a Keller sandwich (KS explants, D). Axial elongation is suppressed in FN explants (C, top view) but rescued in KS explants (E, top view). (F) LWR of LRO cells at a stage 12 equivalent in FN and KS explants summarized on a Tukey boxplot. (G–I) Basal body planar position in LRO cells in situ (G), or in an FN (H) or KS explant (I) at a stage 18 equivalent, plotted in relation to the geometric cell center (center) and the cell edge normalized to one. Plots are aligned to the A-P axis as indicated in KS explant (E) or FN explant (white line, C). Data from different embryos or explants are color coded. (J) Plots of cilia length at the midline of the explants or the LRO (mean ± SD). Full statistics and sample sizes are provided in Table S1.
	Opens large image Figure 3 Strain Promotes Planar Axis Formation in LRO Explants (A–F) LRO explants isolated as indicated (A) were left unstrained (B) or gradually strained (C) by aspiration (white arrow) into a capillary (50 Pa, 3 hr). At a stage 12 equivalent, cell elongation (LWR) and orientation were scored and shown on a Tukey plot (D), or Rose plot (E and F), respectively. The number of cells (explants) scored is indicated. Rose plots indicate the fraction of cells scored that align to the x axis (set to the long axis of the capillary in strained explants or to the mean long axis in unstrained explants), versus orthogonal, y axis. (G–I) The stable fraction of fzd3-GFP (G), vangl2-GFP (H), and celsr1-GFP (I) was measured using FRAP, at junctions in the LRO explants at a stage 12 equivalent, either unstrained or after 3 hr of aspiration (50 Pa). Each point represents a junction measured, randomly chosen in unstrained explants or chosen in strained explants based on whether they lie parallel (P) or orthogonal (O) to the strain axis. Error bars show the mean ± SD. Full statistics and sample size are presented in Table S1.
	Figure 4 Strain Promotes Long Motile Cilia Formation in LRO Explants (A and B) Confocal images of LRO explants at a stage 18 equivalent, either left unstrained (A) or strained for 3 hr using 50 Pa of negative pressure (B), visualizing cell boundaries (blue), basal bodies (green), and cilia (red). Scale bars, 5 μm. (C) Cilia length at a stage 18 equivalent in LRO explants either left unstrained or strained for 3 hr using relatively high (50 Pa) or low (20 Pa) levels of negative pressure, with the mean ± SD indicated. (D and E) Confocal images of representative cilia in strained (E) and unstrained LRO explants, expressing tektin2-GFP, and stained with the acetylated tubulin antibody. Arrows mark basal body location of tektin2-GFP. (F and G) Diagrams (F) illustrating two different strain applications that vary in strain duration (3 versus 1 hr), following by cilia length measurements (G) at a stage 18 equivalent. (H) Cilia length at a stage 18 equivalent in LRO explants that were strained for 3 hr with 50 Pa, with the mean ± SD indicated. Shown are plots of data from individual explants where cilia length is plotted versus cell position in the explant during strain, showing the average for equivalent size bins, the 95% confidence range, and the best-fit curve (Table S2). Full statistics and sample size are provided in Table S1.
	Figure 5 Strain Induces Cilia Positioning and a PCP Vector in a Consistent Planar Direction (A–E) LRO explants (A) were left unstrained (B and D) or strained for 3 hr using 50 Pa of negative pressure (C and E). Basal body position plotted as in Figure 2 with different colors used in these and other panels to represent data from different explants. Plots are oriented along the inside-to-outside axis of the capillary in the strained explants but randomly assigned in the unstrained explants. Examples of basal body positioning data from unstrained (D) and strained explants (E) where the red dot is the geometric center, the blue dot is the basal body, black is the cell edges, and the arrows denote the planar vector. (F–H) Planar positioning of cilia in the LRO in situ (F) shown in polar plots as above, based on data obtained for lateral (G) versus medial cells (H). (I) FRAP analysis of isolated, Fzd3-GFP expressing cells in LRO explants at a stage 12 equivalent. Inside and outside refer to measurements made at cell edges furthest and closest to opening of the capillary during aspiration, respectively. Each point represents a measurement at one edge, with the mean ± SD indicated. (J–Q) Marginal zone explants, centered either 45° (J–M) or 90° (N–Q) from the dorsal midline, were left unstrained (K and O) or strained (L and P) using the same conditions employed for LRO explants. At a stage 18 equivalent, cilia length (M and Q) and planar positioning (K, L, O, and P) were scored and plotted, as above. Full sample size and statistics are presented in Table S1.
	Figure 6 Foxj1 Is Required for Strain-Induced Cilia Differentiation (A–D) Cilia length (D) and planar position (B and C) were measured in the LRO of foxj1 Crispr mutants at stage 18 (A), in cells located laterally (B) or medially (C). (E–H) Cilia length (H) and planar position (F and G) were measured at a stage 18 equivalent in LRO explants isolated from foxj1 mutants (E) and left unstrained (F) or subjected to strain (G) for 3 hr using 50 Pa of negative pressure. Cilia length is shown with the mean ± SD indicated. Full statistics and sample sizes are provided in Table S1.
	Figure 7 Deconstructing Cilia Differentiation in Response to Strain (A–L) Ectodermal explants expressing foxj1 (A–D), nr2 (E–H), or both foxj1/nr2 (I–L) were left unstrained (B, F, and J) or strained for 3 hr using 50 Pa of negative pressure (C, G, and K). At a stage 18 equivalent, cilia length (D, H, and L) and planar positioning (B, C, F, G, J, and K) were scored as described in Figure 5. The axes in (B), (F) and (J) were assigned randomly for each individual explant, with data from a given explant color coded. Polar plots in (C), (G), and (K) are oriented relative to the inside and outside of the capillary during strain. Cilia length is shown with the mean ± SD indicated. Full statistics and sample sizes are provided in Table S1.

Antic, Planar cell polarity enables posterior localization of nodal cilia and left-right axis determination during mouse and Xenopus embryogenesis. 2010, Pubmed, Xenbase

Antic, Planar cell polarity enables posterior localization of nodal cilia and left-right axis determination during mouse and Xenopus embryogenesis. 2010, Pubmed , Xenbase
Beyer, Serotonin signaling is required for Wnt-dependent GRP specification and leftward flow in Xenopus. 2012, Pubmed , Xenbase
Bhattacharya, CRISPR/Cas9: An inexpensive, efficient loss of function tool to screen human disease genes in Xenopus. 2015, Pubmed , Xenbase
Blum, The evolution and conservation of left-right patterning mechanisms. 2014, Pubmed , Xenbase
Blum, Symmetry breakage in the vertebrate embryo: when does it happen and how does it work? 2014, Pubmed , Xenbase
Blum, The Power of Strain: Organizing Left-Right Cilia. 2018, Pubmed
Borovina, Vangl2 directs the posterior tilting and asymmetric localization of motile primary cilia. 2010, Pubmed
Boskovski, The heterotaxy gene GALNT11 glycosylates Notch to orchestrate cilia type and laterality. 2013, Pubmed , Xenbase
Campbell, Foxn4 promotes gene expression required for the formation of multiple motile cilia. 2016, Pubmed , Xenbase
Chien, Mechanical strain determines the axis of planar polarity in ciliated epithelia. 2015, Pubmed , Xenbase
Choksi, Switching on cilia: transcriptional networks regulating ciliogenesis. 2014, Pubmed
Chu, Wnt proteins can direct planar cell polarity in vertebrate ectoderm. 2016, Pubmed , Xenbase
Chu, Prickle3 synergizes with Wtip to regulate basal body organization and cilia growth. 2016, Pubmed , Xenbase
Davidson, Patterning and tissue movements in a novel explant preparation of the marginal zone of Xenopus laevis. 2004, Pubmed , Xenbase
Davidson, Mesendoderm extension and mantle closure in Xenopus laevis gastrulation: combined roles for integrin alpha(5)beta(1), fibronectin, and tissue geometry. 2002, Pubmed , Xenbase
Dobin, STAR: ultrafast universal RNA-seq aligner. 2013, Pubmed
Gomez, Microtubule organization is determined by the shape of epithelial cells. 2016, Pubmed
Hamada, Mechanisms of left-right asymmetry and patterning: driver, mediator and responder. 2014, Pubmed
Harumoto, Atypical cadherins Dachsous and Fat control dynamics of noncentrosomal microtubules in planar cell polarity. 2010, Pubmed
Hashimoto, Planar polarization of node cells determines the rotational axis of node cilia. 2010, Pubmed
Hashimoto, Translation of anterior-posterior polarity into left-right polarity in the mouse embryo. 2010, Pubmed
Heinz, Simple combinations of lineage-determining transcription factors prime cis-regulatory elements required for macrophage and B cell identities. 2010, Pubmed
Heisenberg, Back and forth between cell fate specification and movement during vertebrate gastrulation. 2008, Pubmed
Hellman, The zebrafish foxj1a transcription factor regulates cilia function in response to injury and epithelial stretch. 2010, Pubmed
Keller, Developmental biology. Physical biology returns to morphogenesis. 2012, Pubmed
Keller, Xenopus Gastrulation without a blastocoel roof. 1992, Pubmed , Xenbase
Keller, Vital dye mapping of the gastrula and neurula of Xenopus laevis. I. Prospective areas and morphogenetic movements of the superficial layer. 1975, Pubmed , Xenbase
Keller, Vital dye mapping of the gastrula and neurula of Xenopus laevis. II. Prospective areas and morphogenetic movements of the deep layer. 1976, Pubmed , Xenbase
LeGoff, Mechanical Forces and Growth in Animal Tissues. 2015, Pubmed
Matis, Microtubules provide directional information for core PCP function. 2014, Pubmed
McGrath, Two populations of node monocilia initiate left-right asymmetry in the mouse. 2003, Pubmed
Minegishi, A Wnt5 Activity Asymmetry and Intercellular Signaling via PCP Proteins Polarize Node Cells for Left-Right Symmetry Breaking. 2017, Pubmed
Mitchell, A positive feedback mechanism governs the polarity and motion of motile cilia. 2007, Pubmed , Xenbase
Neugebauer, FGF signalling during embryo development regulates cilia length in diverse epithelia. 2009, Pubmed , Xenbase
Nonaka, De novo formation of left-right asymmetry by posterior tilt of nodal cilia. 2005, Pubmed
Okada, Mechanism of nodal flow: a conserved symmetry breaking event in left-right axis determination. 2005, Pubmed
Quigley, Rfx2 Stabilizes Foxj1 Binding at Chromatin Loops to Enable Multiciliated Cell Gene Expression. 2017, Pubmed , Xenbase
Quigley, Specification of ion transport cells in the Xenopus larval skin. 2011, Pubmed , Xenbase
Robinson, edgeR: a Bioconductor package for differential expression analysis of digital gene expression data. 2010, Pubmed
Roszko, Regulation of convergence and extension movements during vertebrate gastrulation by the Wnt/PCP pathway. 2009, Pubmed
Schier, Nodal signaling in vertebrate development. 2003, Pubmed
Schweickert, The nodal inhibitor Coco is a critical target of leftward flow in Xenopus. 2010, Pubmed , Xenbase
Schweickert, Cilia-driven leftward flow determines laterality in Xenopus. 2007, Pubmed , Xenbase
Shih, Patterns of cell motility in the organizer and dorsal mesoderm of Xenopus laevis. 1992, Pubmed , Xenbase
Shimada, Polarized transport of Frizzled along the planar microtubule arrays in Drosophila wing epithelium. 2006, Pubmed
Shook, Pattern and morphogenesis of presumptive superficial mesoderm in two closely related species, Xenopus laevis and Xenopus tropicalis. 2004, Pubmed , Xenbase
Song, Planar cell polarity breaks bilateral symmetry by controlling ciliary positioning. 2010, Pubmed
Strutt, Dynamics of core planar polarity protein turnover and stable assembly into discrete membrane subdomains. 2011, Pubmed
Stubbs, The forkhead protein Foxj1 specifies node-like cilia in Xenopus and zebrafish embryos. 2008, Pubmed , Xenbase
TUFT, The uptake and distribution of water in the embryo of Xenopus laevis (Daudin). 1962, Pubmed , Xenbase
Tözser, TGF-β Signaling Regulates the Differentiation of Motile Cilia. 2015, Pubmed , Xenbase
Walentek, ATP4a is required for Wnt-dependent Foxj1 expression and leftward flow in Xenopus left-right development. 2012, Pubmed , Xenbase
Walentek, Wnt11b is involved in cilia-mediated symmetry breakage during Xenopus left-right development. 2013, Pubmed , Xenbase
Yoshiba, Cilia at the node of mouse embryos sense fluid flow for left-right determination via Pkd2. 2012, Pubmed
Yoshiba, Roles of cilia, fluid flow, and Ca2+ signaling in breaking of left-right symmetry. 2014, Pubmed