Abstract
Epithelial tubules must have the right length and pattern for proper function. In the nephron, planar cell polarity controls elongation along the proximal-distal axis. As the tubule lengthens, specialized segments (proximal, distal etc.) begin to differentiate along it. Other epithelia need Rho-kinase for planar cell polarity but it is not known whether Rho-kinase is involved in this way in the nephron. We show that Rho-kinase is essential for the morphogenesis of nephrons, specifically for correct cell orientation and volume. We use fluorescent reporter-models and progenitor-specific markers to demonstrate that inhibition of Rho-kinase prevents proper proximal-distal axis formation, causes segments to develop abnormally and progenitor-cell segregation to fail. Our data demonstrate the importance of Rho-kinase in normal nephron tubulogenesis and patterning.
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Introduction
Cellular polarity is a characteristic of all epithelia and the acquisition of polarity is essential for tubulogenesis during embryonic development. Understanding how cell polarities develop and are orientated in vivo is a major research problem: in addition, the possible importance of polarities in maintaining epithelial characteristics is also a much debated matter because renal fibrosis secondary to epithelial-mesenchymal transition is a key feature of chronic kidney failure1,2. Nephrons form by mesenchymal-to-epithelial transitions of progenitor cells3. As they differentiate, these cells acquire both an apical-basal axis across the epithelial plane and a planar proximal-distal axis along the tubule3. Elongation of nephron tubules is regulated by a myosin-dependent mechanism of convergent extension4,5,6. This is in turn controlled by Wnt9b which establishes the planar cell polarity (PCP) along the proximal-distal axis4,5,6. Central to convergent extension in other systems is the Rho-pathway7: in particular Rho-kinase (ROCK) regulates a range of necessary cytoskeletal processes, including microtubule stability, adherens junction formation and myosin stress-fibre formation8,9,10,11. Cell-culture models suggest that the Rho-signalling pathway is vital for the establishment of epithelial polarity12,13,14,15,16,17 and Wnt9b deficient mice5,6 produce ureteric bud defects similar to those caused by the inhibition of ROCK in kidney organ cultures18. Although, Wnt9b and a myosin-dependent convergent extension control aspects of nephron morphogenesis (e.g. elongation)4, it is not clear whether ROCK is also involved. ROCK has not been studied in the context of nephron PCP and although ROCK1 and ROCK2 knockouts are without renal phenotypes19,20, the double knockouts, which would eliminate known redundancy, have not been made21.
Results
Rho-Kinase is required for normal nephron formation
We blocked ROCK function during nephron formation by applying ROCK-inhibitors glycyl-H1152 (hereafter H1152)22,23 and Y2763224, separately, to various embryonic kidney culture systems18,25,26. To monitor effects on nephron development we used kidneys from E12.5 Wt1+/GFP knock-in reporter mice27 and wild-type embryos to track the early nephron and podocyte progenitors28 and antibodies against tubule basement membrane (β-laminin) and the ureteric bud (Calbindin-D28K)29. ROCK-inhibited kidneys contained morphologically abnormal nephrons (Fig. 1b and Fig. S1b–d) compared to controls (Fig. 1a and Fig. S1a,c). We counted the number of morphologically normal and abnormal nephrons in treated and untreated wild-type kidneys (Fig. 1c; see Materials and Methods for scoring criteria). 61% of nephrons forming in ROCK inhibiting conditions (n = 76; from 3 kidneys) displayed morphological abnormalities whilst only 5% of control nephrons (n = 58; from 3 kidneys) did so (p = 0.00145 by Student's t-test).
We and others have previously shown that the ureteric bud is itself affected by ROCK inhibitors18,25 (Fig. 1b and Fig. S1b). We tested whether the there was also a reduction in the number of nephrons, which there was (Student's t-test p = 0.003 for control vs. 2.5 μM H1152) and whether this correlated with a decrease in the number of ureteric bud tips (Fig. 1d) (n = 25 kidneys), which it did (r = 0.94, Pearson coefficient, using all samples from control and all inhibitor concentrations; Student's t-test p = 0.01 for control vs. 2.5 μM H1152). These data raised the possibility that the effects of ROCK inhibition on nephron morphogenesis were secondary to its effects on ureteric bud, We therefore removed the ureteric bud from the system by combining metanephric mesenchyme with spinal cord, a known inducer of nephrogenesis30,31. In controls, nephrons developed normally (Fig. 1e and Fig. S1f) but inhibition of ROCK still caused the formation of aberrant and tangled epithelial structures (Fig. 1f and Fig. S1f). As suggested by previous studies, the nephron mesenchymal-to-epithelial transition itself is not blocked by ROCK inhibition18,25. To test whether the timing of ROCK inhibition influenced the degree to which nephron formation was disturbed, we added the inhibitor at different time-points or withdrew it once added (Fig. S2); E12.5 kidneys were used. Withdrawing the inhibitor after 24 hrs or 48 hrs and culturing in normal medium to a total of 72 hrs allowed nephrogenesis to recover to produce 90% and 60%, respectively, of the total nephrons found in controls. Cultures continuously maintained in inhibitor-conditions (72 hrs) developed only 10% of the total nephrons found in controls. The recovery of nephron numbers seen when the inhibitor was removed after 24 hrs or 48 hrs of culture was significant compared to samples continuously treated with inhibitor (p = 0.0001, p = 0.0003). Adding the inhibitor only at a later time point between 48 hrs and 72 hrs also led to fewer nephrons forming compared to controls (49% of control, p = 0.007): this was not significantly different from those samples exposed to a 24 hr dose of inhibitor at the start of the experiments (p = 0.14). Morphological defects were also seen in nephrons that formed in induced isolated mesenchyme when ROCK was inhibited only after epithelialisation had taken place, during the period of nephron segmentation (Fig. S1g). Together, these data indicate that the effect of ROCK inhibition of nephrons is direct and not secondary to the effect on ureteric bud. qRT-PCR analysis of markers for the major kidney components and processes (Six2 - nephron progenitors, GDNF - ureteric branching, Wnt4 and Lhx1 - nephron induction, Hoxb7 and Wnt11 – ureteric bud) indicated that ROCK inhibition had no significant effect on their expression (Fig. S1e). Hereafter only H1152 was used for experimental consistency and because kinase-inhibition studies have demonstrated a greater degree of specificity for Rho-kinase by H1152 compared to Y-2763223.
Rho-Kinase is required for tubule morphogenesis
Nephron development is highly dynamic so, to visualise and characterise the nephron defects, we set up time-lapse cultures of kidney from Pax8Cre;YFPlox-stop reporter mice32,33. Pax8 is expressed in the ureteric bud, in induced nephron progenitor cells and in the nephron itself34. Pax8Cre;YFPlox-stop kidneys stably express YFP in all nephron lineages (Movie 1: the Pax8Cre;YFPlox-stop reporter mouse cross and lineage tracing experiments are to be fully described in Berry et al. in preparation). We added the ROCK inhibitor either at the start of the experiment, before nephrons formed (Fig. 2b), or only after 48 hrs of culture (Fig. S3a and Movie 2) when nephrons had epithelialised and started segmentation. Both cases resulted in a variety of defects. Nephrons that formed in ROCK-inhibitor conditions epithelialised (i.e. they expressed Cdh1) and initiated segmentation (i.e. they expressed Jag1-in their medial domain) (Fig. 2b and Fig. S3a) in a similar manner to controls (Fig. 2a). Consistently, however, they failed to elongate normally and instead rounded up into cyst-like structures (Movie 2).
Kidney tubules elongate along their proximal-distal axis by a mechanism of convergent extension, resulting in cells that have completed the process being positioned at an angle perpendicular to that of the direction of the tubule4. We investigated whether the morphological defects could be caused by the cells being abnormally polarised. To do this we generated cell 3D reconstructions and measured the orientation of these nephron cells within the tubules, as described elsewhere4 and in Materials and Methods. We measured each cell's orientation compared to the direction of the tubule and calculated the deviation of this value from the 90° angle expected by a perfectly perpendicularly aligned cell. The cell angles were measured as positive numbers, regardless of the direction of the deviation, in order to gain an absolute measure of error that would not be cancelled by equal errors in opposite directions by different cells. In controls, the mean deviation was 17° (Fig. 2c, f; n = 83 cells from 7 nephrons). ROCK inhibitor treated nephrons displayed two distinct sets of cell populations, those which were located within morphologically more normal epithelial tubules (Fig. 2d, g; n = 85 cells; from 6 nephrons) and those within bloated portions of tubules (Fig. 2e, h; n = 61 cells from 5 nephrons). The cells in the more normal tubules averaged a higher mean deviation 25° compared to controls (Fig. 2g; 25°, p = 0.006). Those cells located within bloated tubules displayed a much greater degree of deviation 33° compared to controls (p = 4 × 10−6).
In other tissues, ROCK activity is important for the regulation of cell size35,36. We tested whether the cell size was also altered by ROCK inhibition by analysing the volume of the cells (measured by 3D reconstruction from optical sections). ROCK-inhibited cells from both ‘normal’ and bloated nephron segments showed a large increase (+78%) in cell volume compared to controls (p = 6 × 10−10, n = 94 cells from control conditions vs. 159 cells from H1152 conditions) (Fig. S3b).
Rho-Kinase is required for progenitor segregation but not differentiation
The proximal-distal axis is populated by domains containing different progenitor cells that will give rise to segment-specific lineages. To test whether the cell-polarisation defects affected the specification or location of these progenitor cell populations we performed antibody stains against segment-specific proteins and examined kidneys for regions of abnormal expression overlap. Wt1 and Podxl were used to detect glomerular/podocyte progenitors. Lotus tetragonolobus lectin (LTL) for proximal tubule cells and Jag1 for Loop of Henle and proximal tubule progenitors28,37,38,39,40. The distal tubule displays strong Cdh1 and is negative for the other markers used38. Remarkably, in controls only 4/891 (0.4%) of nephrons examined displayed spatial overlap of segment markers in any area of the nephron (Fig. S4a). In ROCK-inhibitor treated samples, this overlap was still uncommon but increased 10-fold (25/549, 4.5%; Fig. S4a). A Chi Square test was significant to p = 0.001, d.f. = 1 x2 = 29.0. Overlap between WT1+ and JAG1+ domains (i.e. glomerular podocyte and proximal/medial tubule) accounted for 80% of these cases. Wt1 and Jag1 are expressed during the earliest stages of nephron development, whilst LTL binding and Podxl expression is initiated at later time-points. We carried out confocal scans at higher magnification (60×) and these showed a range of segmentation abnormalities: engulfed glomeruli (Fig. 3a and Fig. S4b), overlap of segment-specific expression (Fig. 3b and Fig. S4c) and what appeared as loosely structured glomeruli (Fig. 3c and Fig. S4d).
As ROCK activity can also affect differentiation41 we used qRT-PCR to analyse the expression of 11 genes exclusively expressed in specific nephron-segments (Fig. 3d). It would be expected from data presented above that by applying the ROCK inhibitor we would reduced nephron numbers by ~ 70% (Fig. 1d), thus, any important reduction would have to be greater than this. Expression levels were significantly decreased for 6/11 genes analysed; however, they were decreased by an average of 64% (Fig. 3d), not far from the expected 70% decrease. This suggests that the reduction in gene expression is caused by the decrease in nephron formation rather than by loss of differentiation of any particular nephron segment.
We focused on the nephron defects that displayed abnormal segregation of segment-progenitor cells (Fig. 3b). To determine whether the WT1+ podocyte progenitor cells (Fig. 3b) also extended into the tubular portion of nephrons we again used the Pax8Cre; YFPlox-stop reporter to mark all nephron cells (Fig. 4a). Nephrons displayed WT1+ cells within tubular regions that were also CDH1+ (Fig. 4a). We confirmed this by 3D visualisation (Fig. 4b, Fig. S5a). Another defect perhaps related to tubule identities was the occurrence of nephrons with two connections to the ureteric bud. These were fused at their JAG1+ proximal domain (Fig. 4c and Fig. S5c). To confirm that such nephrons were indeed caused by nephrons abnormally fusing to other nephrons we set up time-lapse experiments of Wt1+/GFP knock-in reporter mice. In ROCK-inhibitor treated Wt1+/GFP kidneys, nephrons occasionally came head-to-head and fused with each other (Fig. 4d and Movie 4). In experimental conditions, 6/6 kidneys displayed such nephron-to-nephron fusions. The number of fusions per kidney ranged from 5 sets to only 1 (average was 2.7). In control conditions (Fig. 4d and Movie 3) such nephron-to-nephron fusions were less frequent (p = 0.049). 4/6 control kidneys displayed fusions at an average of 0.83 fusions per kidney.
Discussion
As the nephron forms, it develops multiple segments that express genes and display properties distinct to each segment. During the process of segmentation it also undergoes a series of complex morphogenetic changes; for instance it connects with the ureteric bud, it elongates and it develops the Bowman's capsule. This division of the nephron into domains is evident from the stage directly after epithelialisation37,42,43. Because the segmentation, patterning, elongation and morphogenesis occur simultaneously, they are likely to at some level be co-dependent. Here, we have demonstrated that Rho-kinase (ROCK) activity is required for both morphogenesis and the patterning of the nephron. With reduced ROCK activity, serious failures of morphogenesis occur and we show that these are associated with the disorientation of cell axes within the nephron tubule. In Xenopus nephrons, the elongation of the nephron tubules is regulated via a process of convergent extension4. This elongation is dependent on Wnt-signalling and a mechanism which controls the precise alignment of cell axes4. Mouse nephrons rely on a similar alignment of cells as the nephron elongates and this requires Wnt9b-PCP signalling6 which is associated with JNK activation and therefore probably with the PCP pathway. Because ROCK is known to be activated in the PCP pathway44 our work therefore brings these observations together to suggest that the PCP pathway acts through ROCK to control cell orientation in the nephron tubule.
ROCK is also required for normal cell migration of pre-epithelial nephron cells25. Although, it is not known at what precise stage the nephron is patterned into separate segments, it is known that, the renal vesicle already displays polarised gene expression directly after epithelialisation37. One possibility is that the specification of nephron segment identities begins prior to epithelialisation when mesenchymal nephron progenitor-cells aggregate and prepare for a mesenchymal-to-epithelial transition. If so, this could indicate that some of the defects observed here result from abnormal migration of cells during pre-epithelial stages of nephron development. This is however unlikely to be the sole mechanism as post-epithelial nephrons are also affected by inhibition of ROCK but it raises questions regarding the importance of cell-migration for early nephron patterning.
Other consequences of losing normal ROCK activity included the failure of some nephrons to connect with the ureteric bud (Figure 2b), the abnormal positioning of the glomerulus within the tubule (Figure 3a) and the disorderly segregation of different nephron segments along the tubules (Figure 3b). ROCK serves an important function for the remodelling of epithelia in other tissues via myosin-dependent mechanisms26,45 and in Drosophila, actin-myosin tension is known to be required for the maintenance of compartment boundaries46. Since ROCK is an activator of myosin, it is possible that in kidneys too, proper epithelial remodelling and compartment boundary formation require adequate actin-myosin tension and this is required for segment segregation. Our data highlight the importance of integrating the mechanisms driving the morphogenesis of the nephron with those that regulate the differentiation programmes that are occurring as the nephron segments.
Methods
Animal experiments
All animal experiments were approved by the Edinburgh University Animal Welfare and Ethical Review Body (AWERB). All animals were kept at the MRC Human Genetics Unit and University of Edinburgh animal facilities. All mice were kept according to regulations specified by the Home Office. Animals were kept and bred under P.H. Project Licence 60/3788 as approved by the Home Office.
Organ cultures
Kidneys were isolated from E11.5–E12.5 mice. Wt1+/GFP (Wt1tm1Nhsn)27 mice were crossed with CD1. Pax8+/Cre (Pax8tm1(cre)Mbu) mice33 were crossed to Rosa26eYFP/eYFP (Gt(ROSA)26Sortm1(EYFP)Cos) animals32; a total of 35 Pax8Cre;YFPlox-stop reporter kidneys were used. 14 in control conditions, 9 with H1152 added at 0 hrs, 7 with H1152 added at 48 hrs and 5 with H1152 added at 72 hrs. 8 kidneys were used for time-lapse. Kidneys were cultured as previously described by Michael et al.18. Isolated mesenchyme was induced using E11.5 dorsal spinal cord in transfilter cultures with the mesenchyme being placed on the top and the spinal cord at the bottom. Controls were carried out using cultures of nephrons formed in transfilter spinal cord-induce mesenchyme where the spinal cord was removed after 24 hrs of induction in order to test whether the effects of inhibitors, on nephrons, were direct (and not secondary to effects on the spinal cord). Control conditions contained an equal volume of inhibitor vehicle. Inhibitors were added at the beginning of culture (t = 0) unless otherwise specified. Culture medium was changed every three days unless otherwise specified.
Quantification of kidney morphology and nephron formation
To quantify the kidney response to ROCK inhibitor, E11.5 kidneys were cultured and treated with a range of ROCK inhibitor concentrations (0, 0.08, 0.16, 0.63, 1.25 and 2.5 μM) for 96 hrs and stained against ureteric bud marker Calbindin D-28K and ureteric bud and nephron marker laminin. Ureteric bud tips and nephrons were counted for each kidney (25 kidneys were used).
The inhibitor-timing experiments were performed by culturing kidneys for 72 hrs in the following conditions (i) control-72 hrs; (ii) 1.25 μM H1152 0–24 hrs + control 24–72 hrs; (iii) 1.25 μM H1152 0–48 hrs + control 48–72 hrs; (iv) 1.25 μM H1152 0–78 hrs; (v) control 0–48 hrs + 1.25 μM H1152 48–72 hrs (26 kidneys were used).
To determine whether nephron segments were forming normally, with respect to morphology and differentiation, a total of 9 kidneys were set up in control and a total of 9 in H1152 conditions and cultured for 120 hrs. In sets of 3 controls and 3 experimental samples, kidneys were stained for Wt1, Jag1, Cdh1; Wt1, LTL, Cdh1; or Podxl, LTL, Cdh1. In control and H1152 conditions 328 and 134 Wt1, LTL, Cdh1 nephrons were analysed, 366 and 300 Wt1, Jag1, Cdh1 nephrons; and 197 and 115 Podxl, LTL, Cdh1 nephrons. Nephrons were visually scored for abnormal overlap of markers as compared to controls. Thus 891 nephrons in control and 549 nephrons in H1152 conditions were analysed in total.
To quantify nephron abnormality in response to ROCK inhibition, E11.5 kidneys were cultured for 120 hrs. The ROCK inhibitor was added after 48 hrs to focus on defects caused by morphogenesis rather than formation. Cultures were stained for β-laminin and Cdh1 to show the basement membrane and the morphology of the nephrons and samples were subsequently scanned using confocal microscopy. Samples used 3 kidneys per treatment and such nephrons that were clearly identifiable were individually staged according to GUDMAP ontology (www.gudmap.org) and Little et al 200747; 58 nephrons were scored for control conditions and 72 nephrons for H1152 conditions. Nephrons were subsequently categorised according to morphology - using both the β-laminin and Cdh1 antibody stains as visual markers. Nephrons with obvious morphological abnormal tubules and structures were scored as ‘abnormal’ and such that were typical of stage and morphology were scored ‘normal’. Where nephrons could not with certainty be assigned normal or abnormal morphology scores, these were classified as ambiguous.
3D reconstructions, volumetric analyses, cell orientation
Confocal stacks (1 μm steps, captured at 60 ×, 1024 × 1024 pixels at 0.2071602 μm/pixel) of whole nephrons were loaded into TrakEM2 - Fiji (http://fiji.sc/). The automatic segmentation tools were found to be insufficient in separating individual cells whereas manual marking was found to be more robust and was therefore utilised. Cells were thus manually marked throughout each cell's z-plane. The annotated cells were exported as tiff-stacks and remerged with the original stacks. Cell orientations were measured against the plane of the nephron segment where the cells were located. The cell orientation was taken as the broadest point of the cell. All angles measured were within 0°–180°degrees. The angles were plotted against the frequency. The deviation from 90° (which would indicate a cell perfectly orthogonal to the plane) was used for statistical comparison between groups. The cell volumes of the reconstructed cells were automatically calculated using TrakEM2. A total of 30-kidneys were scanned at low magnification (10×), 8 control nephrons and 13 ROCK-inhibitor treated nephrons were scanned at 60×. 7, 6 and 5, control, ‘normal’ and ‘bloated’, tubules were used for the cell reconstructions.
Immunohistochemistry and inhibitors
Kidneys were fixed on filters in −20°C methanol prior to 1 hr washes and antibody incubations in PBS. Primary and secondary antibody incubations were carried out at 4°C over night. Antibodies were diluted in 1 × PBS. Samples were mounted in 1:1 Glycerol:1 × PBS or Vectashield, sealed with Lizzie/Pink varnish and visualised on a Leica TCS-NT laser scanning confocal microscope, Zeiss Axio Imager.A1 or Nikon A1R. Time-lapse imaging was carried out using a Nikon TiE inverted microscope. Primary antibodies were used at the following concentrations: anti-Laminin (L9393/SIGMA), anti-CD15 (M0733/DAKO), anti-CDH1 (610181/BD), anti-Pan-cytokeratin (C2562/SIGMA), anti-WT1 (sc-192/SANTA CRUZ), anti-JAG1 (R&D Systems). Nuclei were stained with TO-PRO-3 iodide (T3605/MOLECULAR PROBES), 1:250. Secondary antibodies were purchased from SIGMA and Molecular Probes. Rho-kinase inhibitor Y27632 (Y0503/SIGMA) was reconstituted in dH2O, stored at −20°C and used at 10 μM–20 μM; 20 μM was used. Glycyl-H1152 dihydrochloride (2485/TOCRIS) was reconstituted in dH2O, stored at −20°C and used at a range of 1.25 μM–2.5 μM; 1.25 μM was used in all experiments except for experiment shown in (Fig. 1d) looking at dosage-response.
Segment-specific gene expression
To isolate RNA, cultured control and experimental kidneys were placed in RNALater (Ambion) for stabilisation. A minimum of 9 kidneys were used per condition, with 3 kidneys per replicate. The RNA isolated and used for quantification was the same in Figure 3 and Figure S1. RNA isolation was performed using RNeasy Micro kits (Qiagen) from the whole kidneys. 500 μg RNA was used for cDNA synthesis using SuperScript II Reverse Transcriptase (Invitrogen) with Random Primers (Promega). qRT-PCR assays were performed using the Universal Probe Library (Roche) and all primers/probes were designed using the Universal Probe Library Assay Design Center (http://www.roche-applied-science.com/sis/rtpcr/upl/index.jsp?id=UP030000). The primers and probes used were: Slc12a1 (F: tatttgcacaaacggagtgg R: aagctccgggaaatcaggta probe:10) p = 0.109; Slc12a3 (F: cctccatcaccaactcacct R: ccgcccacttgctgtagta probe:12) p = 7.28 × 10−8; Slc3a1 (F: ccatgtcaacggtgtaacca R: gccagctggagtttccatac probe:102) p = 0.316; Slc4a4 (F: actgtctccagtgcaagtagga R: tgtcagattcctgtgggtca probe:26) p = 0.579; Jag1 (F: gaggcgtcctctgaaaaaca R: acccaagccactgttaagaca probe:6) p = 0.279; Irx2 (F: gaagcaaggaggagagttcaga R: gtgagcgagtcgacgtgtag probe:98) p = 2.85 × 10−5; Dll1 (F: gggcttctctggcttcaac R: taagagttgccgaggtccac probe:103) p = 0.181; Synap (F: gtagccaggtgagccaagg R: ttttcggtgaagcttgtgc probe:67) p = 0.006; Podocin (F: ccatctggttctgcataaagg R: ccaggacctttggctcttc probe:38) p = 0.006; Podxl (F: cctgcatctcactcccataat R: tctgttgatgttgtggcactt probe:21) p = 0.001; Nephrin (F: aacatccagctcgtcagcat R: agggctcacgctcacaac probe:25) p = 0.002; Hoxb7 (F: ctggatgcgaagctcagg R: ccgagtcaggtagcgattgta probe:1) p = 0.119; Wnt11 (F: gagctcgcccccaactac R: ggcatacacgaaggctgact probe:85) p = 0.231; Wnt4 (F: ctggactccctccctgtctt R: atgcccttgtcactgcaaa probe:62) p = 0.489; Lhx1 (F: aatgcaacctgaccgagaag R: cgcatttggtaccgaaacat probe:7) p = 0.112; Gdnf (F: tccaactgggggtctacg R: gacatcccataacttcatcttagagtc probe:70) p = 0.935; Six2 (F: caagtcagcaactggttcaaga R: actgccattgagcgagga probe:5) p = 0.275. Statistical analyses were performed using Student's t-tests against controls. Every TaqMan assay used a mouse Gapdh internal control (Roche) and was run twice in repeated triplicates. The assays were run on a Light Cycler 480 (ROCHE) using 384-well plates, 60 × cycles of 95°C 10 s, 60°C 30 s, 72°C 1 s.
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Acknowledgements
We thank Paul Perry and Matthew Pearson for advice with time-lapse and confocal microscopy. We thank Rachel Berry and Anna Thornburn for providing the necessary animals. This work was supported by EuReGene, a Framework 6 program grant by the EU (05085) and the NC3Rs (G1000159).
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N.O.L. and J.A.D. designed the experiments and N.O.L. performed experiments. P.H. provided Pax8Cre;YFPlox-stop and Wt1+/GFP models and assisted with manuscript preparations. N.O.L. and J.A.D. analysed experiments and wrote the manuscript.
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Lindström, N., Hohenstein, P. & Davies, J. Nephrons require Rho-kinase for proximal-distal polarity development. Sci Rep 3, 2692 (2013). https://doi.org/10.1038/srep02692
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DOI: https://doi.org/10.1038/srep02692
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