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Strabismus regulates asymmetric cell divisions and cell fate determination in the mouse brain

Department of Developmental and Regenerative Biology, Mount Sinai School of Medicine, New York, NY 10029

Correspondence to Sergei Y. Sokol: sergei.sokol{at}mssm.edu

The planar cell polarity (PCP) pathway organizes the cytoskeleton and polarizes cells within embryonic tissue. We investigate the relationship between PCP signaling and cell fate determination during asymmetric division of neural progenitors (NPs) in mouse embryos. The cortex of Lp/Lp (Loop-tail) mice deficient in the essential PCP mediator Vangl2, homologue of Drosophila melanogaster Strabismus (Stbm), revealed precocious differentiation of neural progenitors into early-born neurons at the expense of late-born neurons and glia. Although Lp/Lp NPs were easily maintained in vitro, they showed premature differentiation and loss of asymmetric distribution of Leu-Gly-Asn–enriched protein (LGN)/partner of inscuteable (Pins), a regulator of mitotic spindle orientation. Furthermore, we observed a decreased frequency in asymmetric distribution of the LGN target nuclear mitotic apparatus protein (NuMa) in Lp/Lp cortical progenitors in vivo. This was accompanied by an increase in the number of vertical cleavage planes typically associated with equal daughter cell identities. These findings suggest that Stbm/Vangl2 functions to maintain cortical progenitors and regulates mitotic spindle orientation during asymmetric divisions in the vertebrate brain.

© 2009 Lake and Sokol
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	Introduction

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The planar cell polarity (PCP) pathway maintains cell polarity in the plane of epithelial tissues in Drosophila melanogaster embryos through the complex interplay of several core molecular components, including Frizzled, Dishevelled, Strabismus (Stbm), and Prickle (Tree et al., 2002). The same proteins also regulate polarized cell intercalation during gastrulation and neurulation in vertebrate embryos and polarization of inner ear cells in mammals (Sokol, 2000; Kibar et al., 2001; Jessen et al., 2002; Montcouquiol et al., 2003; Torban et al., 2004). In many cases, the PCP pathway has been proposed to modulate the cytoskeleton and influence cell morphology rather than cell fates (Wolff and Rubin, 1998). Nevertheless, some PCP components are essential for asymmetric cell division (ACD) of Drosophila sensory organ precursors (SOPs; Gho and Schweisguth, 1998; Bellaiche et al., 2004). Specifically, the transmembrane protein Stbm promotes the anterior cortical localization of partner of inscuteable (Pins), an activator of G protein signaling, which is required for proper orientation of the mitotic spindle and SOP daughter cell identity (Bellaiche et al., 2004). Although SOP divisions represent a highly specialized system, these observations suggest that the PCP pathway might influence cell fate determination during asymmetric division of other progenitor cells, as defined by unequal inheritance of fates between daughter cells and asymmetric distribution of specific proteins that may control this process. Given the potential importance of ACD in cell fate determination in the vertebrate brain, we investigated the possible involvement of PCP signals in regulating mammalian neurogenesis.

The development of the complex cytoarchitecture of the mammalian brain is thought to depend on the balance between symmetric and asymmetric divisions of neural progenitors (NPs) occupying the ventricular zone (VZ; Chenn and McConnell, 1995; Kosodo et al., 2004; Noctor et al., 2004; Gotz and Huttner, 2005). Vertical cleavage planes that are perpendicular to the ventricular surface usually result in symmetric divisions, whereas horizontally shifted cleavage planes may lead to asymmetry (Chenn and McConnell, 1995; Haydar et al., 2003; Kosodo et al., 2004; Gotz and Huttner, 2005). The latter were hypothesized to play a role in the specification of neuronal fates through unequal inheritance of localized determinants (Betschinger and Knoblich, 2004; Gotz and Huttner, 2005). A disruption in the number of asymmetric divisions may deplete the progenitor population, leading to reduced brain size (Bond et al., 2002) and precocious neuronal differentiation (Sanada and Tsai, 2005). Therefore, factors regulating mitotic spindle orientation are expected to maintain the pool of NPs and regulate the sequential differentiation of cortical neurons and glia (Qian et al., 2000; Shen et al., 2006). Although a conserved Pins/G protein–dependent mechanism was found to regulate mitotic spindle orientation in mammalian VZ progenitors (Sanada and Tsai, 2005; Konno et al., 2008), the involvement of PCP signals in this process has yet to be examined.

	Results and discussion

Top Abstract Introduction Results and discussion Materials and methods References

 
To investigate a possible role of conserved PCP machinery in regulating vertebrate neurogenesis, we examined Lp/Lp (Loop-tail) mice that carry a point mutation in Vangl2 (Kibar et al., 2001). This gene encodes a mammalian homologue of Stbm, a specific component of the PCP pathway in Drosophila (Wolff and Rubin, 1998; Montcouquiol et al., 2003). We constructed a mutated Stbm/Vangl2 cDNA carrying the Lp/Lp mutation that converts a serine to asparagine (S464N). The corresponding StbmS464N protein delocalized from the plasma membrane and failed to inhibit convergent extension movements in Xenopus laevis embryos, supporting the proposed loss of function phenotype of Lp/Lp mice (Fig. S1). Furthermore, although Vangl2 protein was broadly expressed in neuroepithelium of wild-type embryos, it was undetectable in Lp/Lp mice (Fig. S1, A–D), which is consistent with a previously reported loss of protein stability (Torban et al., 2007). Embryonic day (E) 15.5 cerebral cortices from Lp/Lp mice were relatively similar to those of Lp/+ and +/+ mice in both gross morphology (Fig. S2) and a number of progenitors (RC2; Fig. 1, A and B) and revealed only a slight reduction in the neuronal layer (βIII-tubulin or TuJ1; Fig. 1, C and D). However, the number of Reelin-positive Cajal-Retzius cells, the earliest born neurons (Chae et al., 2004), was significantly increased in Lp/Lp cortices as compared with wild-type cortices (Fig. 1, E–G; and Table I). The total number of DAPI-positive nuclei in the marginal layer was largely unaffected, indicating that the increase is not caused by compaction of cells in the mutant cortex (Table I). These observations suggest precocious differentiation of Lp/Lp NPs into early-born neurons.

View larger version (73K): [in this window] [in a new window] [Download PPT slide]   Figure 1. Increased number of Reelin-positive neurons in E15.5 Lp/Lp cerebral cortices. (A–F) Coronal sections of Lp/Lp or wild-type cortices (E15.5) were stained for RC2 (A and B), TuJ1 (C and D), Reelin (E and F, green), and DAPI (blue). (G) The number of Reelin-positive neurons is increased in three different Lp/Lp embryos (15.8 ± 1.9 per field, scored over four 110-µm-wide fields; F) as compared with wild-type mice (5.8 ± 1.3 per field; E). The total number of DAPI-positive nuclei in the marginal layer (scored over six 100-µm-wide fields per genotype) is 72.2 ± 7.4 for Lp/Lp and 61.2 ± 8.3 for wild-type littermates. Error bars indicate mean ± SD. Bars, 50 µm.

View larger version (108K): [in this window] [in a new window] [Download PPT slide]   Figure 2. Precocious differentiation of NPs in Lp/Lp mice. (A–H) Coronal sections of Lp/Lp cortices at E18.5 are shown. They are reduced in size and show premature depletion of progenitors. Histological analysis of E18.5 neocortex, hematoxylin/eosin staining, and the corresponding TuJ1 staining (right) are shown for wild-type and Lp/+ (A) and Lp/Lp (B) cortices. The respective positions of the pial layer (P), marginal zone (MZ; layer I), cortical plate (CP; layers II–VI), sub-VZ (SVZ), and VZ are shown. The corresponding regions examined in C–H are also shown. The astrocytes marked by GFAP (C and F), radial glia progenitors marked by RC2 (D and G), and late-born outer layer neurons marked by Brn-1 (E and H) were all significantly reduced in Lp/Lp mice. Brackets in E and H represent the relative size of the Brn-1 layer. Bars, 50 µm.

View larger version (35K): [in this window] [in a new window] [Download PPT slide]   Figure 3. Precocious differentiation of Lp/Lp NPs in vitro. Progenitors derived from the E18.5 cerebellum (Cm) or E14.5 cortex (Cx) were obtained from Lp/Lp mice and compared with NPs obtained from Lp/+ and/or +/+ littermates. Cerebellar progenitors were also obtained and compared between two different Lp/Lp mice. Dissociated cells were cultured in vitro under conditions that promote sequential neuronal then astrocytic differentiation. (A–C) In the absence of bFGF/EGF for 2 d, NPs formed TuJ1-positive neurons. (D–F) Addition of 2% serum to these cells at day 3 and culture for four additional days allowed astrocyte differentiation that was scored by GFAP staining. (A, B, D, and E) Images shown are for cerebellar progenitors. Frequencies of TuJ1+ (C) and GFAP+ (F) cells were scored per total number of DAPI-positive cells. Error bars indicate mean ± SD. Bar, 50 µm.

LGN localization was evaluated in cultures of dividing NPs isolated from wild-type, heterozygous, and mutant mouse embryonic brains after 24 h of differentiation in the bFGF/B27 medium (Fig. 4, A–F; Table II; Qian et al., 2000). Under these conditions, Lp/Lp NPs had a reduced number of mitoses after 3 d of culture as compared with Lp/+ NPs (Fig. S3, C–E) but revealed increased TuJ1 expression consistent with enhanced neuronal differentiation (Fig. S3, F and C). Cultures were additionally treated with nocodazole to synchronize mitotic NPs for analysis of endogenous LGN asymmetry during each phase of the cell cycle. This permitted enrichment of mitotic progenitors without any apparent disruption in LGN distribution. Asymmetric LGN was detectable in a subcortical crescent in over a third of wild-type cells at prophase (Fig. 4, A–C) and prometaphase/metaphase, when it was found adjacent to the spindle poles (Fig. 4, D–F; and Table II). By anaphase, few asymmetries were visible (6.9% ± 3.3% of wild type), as LGN localized primarily to the cell center or midbody (n = 123; unpublished data). This indicates that spindle orientation is likely determined early within the cell cycle before separation of daughter chromosomes at anaphase. In two independent Lp/Lp cultures, the frequency of cells with asymmetrically distributed LGN was significantly decreased at both prophase and prometaphase/metaphase (Fig. 4, C and F; and Table II). These findings indicate that the Stbm/Vangl2 function in maintaining spindle orientation is conserved in neuronal precursors from Drosophila to mammals.

View larger version (50K): [in this window] [in a new window] [Download PPT slide]   Figure 4. Reduced number of asymmetric divisions in Lp/Lp progenitors. NPs were allowed to differentiate for 24 h in the bFGF/B27 medium. (A, B, D, and E) 0.4 µg/ml nocodazole was added for the last 6.5 h and removed 0.5 h before cells were fixed and costained with antibodies against -tubulin, LGN, and DAPI. Prophase (A and B) and prometaphase/metaphase (D and E) cells were identified by -tubulin localization and exhibited either asymmetric (A–A'' and D–D'') or symmetric (B–B'' and E–E'') localization of LGN. The total number of cell divisions with LGN asymmetry (C and F) was scored at prophase (Lp/Lp embryo 1, n = 257; Lp/Lp embryo 2, n = 294; Lp/+, n= 228; +/+, n = 207) and prometaphase/metaphase (Lp/Lp embryo 1, n = 416; Lp/Lp embryo 2, n = 445; Lp/+, n = 351; +/+, n = 331). Statistical significance was determined against the Lp/+ condition by a standard two-tailed Student's t test (*, P < 0.05; **, P < 0.01). Error bars indicate mean ± SD. Bar, 5 µm.

View larger version (88K): [in this window] [in a new window] [Download PPT slide]   Figure 5. Asymmetric divisions of NPs in the developing cortex. (A and B) Coronal cryosections of E14.5 Lp/Lp (n = 3) and Lp/+ (n = 3) forebrains were stained for phosphohistone H3 (PH3) to identify dividing VZ progenitors. Apical surfaces facing the lateral ventricle are indicated by nonphosphorylated (activated) β-catenin (ABC) staining. (C–F) Only cells adjacent to the lateral ventricle were analyzed and shown with their apical surfaces oriented down. Asymmetric (C–C'' and E–E'') and symmetric (D–D'' and F–F'') centrosomal localization of NuMa at prometaphase (C–D) and anaphase (E–F). Metaphase to anaphase NuMa asymmetries are summarized in G. Images shown are of Lp/+ (C) and Lp/Lp (D–F) cortices. Arrows indicate centrosomes. (H–J) Cleavage plane orientation with respect to the apical surface was scored as described in Materials and methods and is presented in three broad categories: 60–90°, 30–60°, and 0–30°. Representative images are shown. Boxed regions indicate telophase nuclei represented graphically. (K) Comparison of cleavage plane orientation during anaphase/telophase of cortical cell divisions in Lp/+ (n = 172) and Lp/Lp (n = 112) embryos (three for each genotype). Statistical significance was determined by a standard two-tailed Student's t test (**, P < 0.01). Error bars indicate mean ± SD. Bars: (B) 25 µm; (D'', F'', and J) 5 µm.

Consistent with a role in ACD, inhibition of G protein activity decreased asymmetric VZ cleavage planes and increased precocious neuronal differentiation in the mouse cortex (Sanada and Tsai, 2005). Similarly, in Lp/Lp embryos, the reduced asymmetry in distribution of LGN in vitro or NuMa in vivo was associated with precocious neuronal differentiation and depletion of the progenitor population. We propose that Lp/Lp NPs undergo an increased frequency of symmetric neurogenic divisions that normally occur during late stages of cortical development (Haydar et al., 2003). These results support a conserved role for Vangl2 in promoting ACD to preserve the pool of progenitors needed to complete multiple rounds of neurogenesis. Although it is likely that this function of Vangl2 is accomplished through its interactions with Dlg, LGN, and NuMa (Bellaiche et al., 2004; Du and Macara, 2004), this role may be permissive rather than instructive, as Vangl2 protein does not appear to be localized in embryonic brain cells at E12.5 (Fig. S1 B). Further studies are needed to identify direct molecular targets and upstream modulators of Vangl2 to understand the complex regulation of cell renewal and differentiation in the developing cortex.

	Materials and methods

Top Abstract Introduction Results and discussion Materials and methods References

 
Mouse embryos
Lp/Lp mice of the Lp/Lp/Le stock were provided by D. Sassoon (Mount Sinai School of Medicine, New York, NY) and were maintained as described previously (Montcouquiol et al., 2003). For histology, E18.5 embryos (Lp/Lp, n = 4; Lp/+, n = 2) were fixed, embedded in paraffin, sectioned at 10–12 µm, and stained with hematoxylin/eosin.

NP culture
NPs were dissociated from E14.5 forebrain (cortical hemispheres) or E18.5 cerebella using 0.25% trypsin and/or gentle trituration. Single cells were seeded at a density of 10⁵ cells/cm² in DME/F12 media containing N2 supplement (Johe et al., 1996), 10 ng/ml bFGF, 10 ng/ml EGF (Invitrogen), and 2% B27 supplement (Invitrogen). Neurospheres were passaged using Versene (Invitrogen) and/or gentle trituration and reseeded at a density of 1.25 x 10⁴ cells/cm² without B27. All experiments were performed with NPs that were dissociated from passage 3–5 neurospheres.

Differentiation of dispersed NPs was on coverslips coated with poly-L-ornithine (Sigma-Aldrich) and laminin (Invitrogen). For sequential neuronal and astrocytic differentiation, NPs (2–6.5 x 10⁴ cells/cm²) were cultured without bFGF/EGF. Cells were fixed and stained after 2 d. DAPI-positive cells were scored for TuJ1 staining at 40x magnification in 4 (cerebellar) or 10 (cortical) fields per experimental group (25–50 cells per field). For astrocyte (GFAP) differentiation, 2% FCS was added to the medium after 3 d, and cells were stained on day 7. Scoring was performed as described for TuJ1 (with 50–100 cells per field). For analysis of ACD, NPs (4.5 x 10⁴ cells/cm²) were cultured 1–7 d in a defined medium (N2-ST: DME/F12/N2, 2% B27 supplement [Invitrogen], 10 ng/ml bFGF, and 1 mM N-acetyl-L-cysteine [Sigma-Aldrich]; Qian et al., 2000). For LGN localization, 400 ng/ml nocodazole (Sigma-Aldrich) was added after 17 h, incubated for 6.5 h, and removed 0.5 h before fixation and staining. Frequency of LGN asymmetric distribution was over four independent experiments, including one replicate experiment scored blind. All means and SDs were generated using Excel (Microsoft).

Immunofluorescence
The following antibodies were used: TuJ1 (1:500; Covance), GFAP (1:100; Invitrogen), RC2 and Nestin (1:50; Developmental Studies Hybridoma Bank), LGN (1:100; provided by S. Lanier, Louisiana State University Health Sciences Center, New Orleans, LA; Blumer et al., 2002), -tubulin (1:500; B512; Sigma-Aldrich), Reelin (1:350; EMD), Brn-1 (1:50; Santa Cruz Biotechnology, Inc.), ABC (1:200; Millipore), NuMa (1:50; Santa Cruz Biotechnology, Inc.), -tubulin (1:100; Santa Cruz Biotechnology, Inc.), phosphohistone H3 (1:300; Cell Signaling Technology), cleaved caspase 3 (1:100; Cell Signaling Technology), pan-cadherin (1:100; Santa Cruz Biotechnology, Inc), Vangl2 (1:300; provided by M. Montcouquiol, Institut des Neurosciences de Bordeaux, Bordeaux, France), and secondary antibodies against mouse, goat, or rabbit IgG conjugated to Alexa Fluor 488 (1:100; Invitrogen), Cy3, or Cy5 (1:100; Jackson ImmunoResearch Laboratories). Specificity of LGN antibody (Fig. S3 G) was determined by Western blotting lysates from cerebellar Lp/Lp and Lp/+ NPs, E13.5 whole brain, and from Xenopus embryos injected with mRNA as described previously (Brott and Sokol, 2005) with human LGN (hLGN) mRNA (Applied Biosystems) transcribed from pcDNA-hLGN (provided by S. Lanier). For Xenopus Stbm (XStbm) functional assays, mRNA (Applied Biosystems) was synthesized from pCS2+CFP-XStbm (provided by M. Mlodzik, Mount Sinai School of Medicine, New York, NY) and pCS2+CFP-XStbmS464N. pCS2+CFP-XStbmS464N was generated by Pfu-directed mutagenesis as described previously (Brott and Sokol, 2005) using the primer 5'-GGCAAAGCAGTGGACGCTGGTTAACGAGGAACCCGTCACCAACG-3' and confirmed by sequencing. For Western analysis, anti-GFP (JL8; BD) detected XStbm proteins, and anti–β-tubulin (BioGenex) controlled protein loading.

Immunofluorescence experiments of the telencephalic hemispheres were performed at similar points along the anterior posterior axis. Brain tissue from E18.5 Lp/Lp (n = 4), Lp/+ (n = 2), and +/+ (n = 2) mouse embryos was embedded in O.C.T. (Tissue-Tek; Sakura Finetek) and sectioned coronally (10 µm) using a cryostat (Leica). E15.5 Lp/Lp (n = 3) or +/+ (n = 3) were sectioned longitudinally. For asymmetry scoring, E14.5 Lp/Lp (n = 3) and Lp/+ (n = 3) brains were sectioned coronally (8 µm). Sections were postfixed 15–30 min with paraformaldehyde and 2 min in acetone (or acetone alone for GFAP). Antibody incubations were in PBS-TB (PBS containing 0.2% Triton X-100, 5% donkey or goat serum, and 1% BSA), and washes were in PBS containing 0.2% Triton X-100. For staining NP cultures, cells were fixed in paraformaldehyde (30 min), blocked in 10% goat or donkey serum, and incubated with antibodies in 1.5% serum. Stained samples were mounted in VectaShield (Vector Laboratories) containing DAPI or propidium iodide.

Images were obtained using Axiovision software (Carl Zeiss, Inc.), a microscope (AxioImager; Carl Zeiss, Inc.), and a monochrome X camera (Carl Zeiss, Inc.) at room temperature with fixed samples mounted in VectaShield mounting medium. Basic adjustments were performed using either Axiovision software and/or Photoshop (Adobe). Cell images were obtained using 5, 10, 20, 40, and 63x oil objectives with the Apotome attachment (Carl Zeiss, Inc.). Composite images (Fig. S1, A and B) involved overlaying multiple individual fields from a single section in Photoshop. For cleavage plane orientation, anaphase and telophase progenitors were identified in cortical sections costained with -tubulin and DAPI, and the angle between the line segregating daughter chromosomes and the ventricular surface was determined using the AxioVision imaging software. For analysis, division angles were grouped into bins at either 10 or 30° increments. Means and standard deviations were generated using Excel. Statistical significance was determined by a standard two-tailed Student's t test.

RT-PCR analysis of NPs
RNA was extracted (RNeasy; QIAGEN) from cerebellar (passage 4) or cortical (passage 3) neurospheres for cDNA synthesis with Superscript II (Invitrogen) as recommended by the manufacturer. PCR conditions and primer sequences for Dlx2, BLBP (fabp7), Mash1, and Glast (slc1a3) were as described previously (Conti et al., 2005). Additional primer sequences were Nestin (forward, 5'-AGGAACCAAAAGAGACAGGTG-3'; reverse, 5'-TTCCTCAGATGAGAGGTCAGA-3') and GAPDH (forward, 5'-TTCACCACCATGGAGAAGGC-3'; reverse, 5'-GGCATGGACTGTGGTCATGA-3').

Online supplemental material
Fig. S1 shows Vangl2 expression, subcellular localization, and functional activity. Fig. S2 shows characterization of cell proliferation and apoptosis in Lp/Lp cortices. Fig. S3 shows gene expression and growth properties of Lp/Lp NPs. Western blots show specificity of the LGN antibody. Online supplemental material is available at http://www.jcb.org/cgi/content/full/jcb.200807073/DC1.

	Acknowledgments

 
We thank D. Sassoon and M. Kelley for Lp/+ mice, S. Lanier and J. Blumer for the LGN antibody and pcDNA-hLGN plasmid, M. Mlodzik for pCS2+CFP-XStbm, and D. Devenport and M. Montcouquiol for the Vangl2 antibody. We also thank J. Hebert and R. Krauss for critical comments on the manuscript.

This study was supported by the National Institutes of Health grants to S.Y. Sokol and the National Sciences and Engineering Research Council of Canada postdoctoral fellowship to B.B. Lake.

Submitted: 14 July 2008

Accepted: 6 March 2009

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