Abstract
Background
The actin cytoskeleton-associated protein palladin plays an important role in cell motility, morphogenesis and adhesion. In mice, Palladin deficient embryos are lethal before embryonic day (E) 15.5, and exhibit severe cranial neural tube and body wall closure defects. However, the mechanism how palladin regulates the process of cranial neural tube closure (NTC) remains unknown.
Methods
In this paper, we use gene knockout mouse to elucidate the function of palladin in the regulation of NTC process.
Results
We initially focuse on the expression pattern of palladin and found that in embryonic brain, palladin is predominantly expressed in the neural folds at E9.5. We further check the major cellular events in the neural epithelium that may contribute to NTC during the early embryogenesis. Palladin deficiency leads to a disturbance of cytoskeleton in the neural tube and the cultured neural progenitors. Furthermore, increased cell proliferation, decreased cell differentiation and diminished apical cell apoptosis of neural epithelium are found in palladin deficient embryos. Cell cycle of neural progenitors in Palladin -/- embryos is much shorter than that in wt ones. Cell adhesion shows a reduction in Palladin -/- neural tubes.
Conclusions
Palladin is expressed with proper spatio-temporal pattern in the neural folds. It plays a crucial role in regulating mouse cranial NTC by modulating cytoskeleton, proliferation, differentiation, apoptosis, and adhesion of neural epithelium. Our findings facilitate further study of the function of palladin and the underlying molecular mechanism involved in NTC.
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Background
Neurulation is the process that gives rise to the central nervous system, whereby the neural plate undergoes bending, elevating, fusion and remodeling to form the neural tube [1, 2]. In the mouse, neurulation is divided into two phases, primary and secondary neurulation. The brain and most of the spinal cord are created during primary neurulation, while the rest of the spinal cord is created during secondary neurulation. In primary neurulation, NTC is typically initiated at the midline of the hindbrain/cervical boundary, which is termed closure 1. Then neural tube fusion proceeds bi-directionally, toward both the hindbrain and the spinal cord. NTC also initiates at the midbrain/forebrain boundary and the rostral end of the forebrain, these two initiation points are designated closure 2 and closure 3, respectively. Then closure 2 proceeds caudally and rostrally, closure 3 proceeds caudally. After closure 2 meets closure 1 at the midbrain/hindbrain neuropore, and closure 3 meets closure 2 at the anterior neuropore, the whole neural tube closes completely [1, 3]. With the contribution of genetic and environmental factors, neural tube may fail to close, causing neural tube defects (NTDs) [4]. NTDs are the second most common birth defects with an incidence of 1:1000 in human births, after congenital heart defects [3]. In terms of occurring at different axial levels, there are three types of NTDs: exencephaly, spina bifida and craniorachischisis, representing the cranial region NTDs, spinal cord NTDs and NTDs along the entire body axis, respectively [5].
Animal models ranging from flies to mice have been used to explore the mechanisms underlying NTC [6,7,8,9,10]. By 2009, the number of mouse mutants and strains with NTDs exceeds 240, including 205 specific genes, 30 unidentified genes, and 9 multifactorial strains. These genes encode many diverse proteins that participate in cellular functions and biochemical pathways [11]. With in toto live imaging of mouse morphogenesis technology, the NTC process can be observed intuitively [12, 13]. Cellular events involved in NTC have been clarified, including actin organization, proliferation, differentiation, apoptosis, adhesion and so on [9, 10, 14]. However the molecular mechanisms behind the complex process remain poorly understood.
Palladin was first found to be one of genes whose expressions were up-regulated in acute promyelocytic leukemia cell line NB4 with all-trans retinoic acid (ATRA) treatment [15]. Shortly thereafter, it was reported to colocalize with α-actinin in stress fibers [16]. To study the function of palladin in vivo, we previously generated palladin gene knockout mice through homologous recombination, and observed NTD in palladin deficient embryos which died before E15.5 [17]. We demonstrated that peripheral nerves were not significantly stunted and neurite outgrowth was not impaired in Palladin -/- embryos [18]. However the reason that deletion of palladin causes NTD was still unknown. Over the past years, research on palladin has been focused on its interacting proteins [19, 20], its role in tumorigenesis and tumor invasion [21,22,23,24]. There are no other but our previous reports on studying its role in NTC. With the gene knockout mouse model, we have the advantages to study the role that palladin plays during NTC process. In this article, we describe that palladin expresses predominantly in the neural folds at E9.5 in wt mouse embryonic brain. NTD caused by palladin deficiency exhibits normal neural tube closure 1 but defective closure 2 and closure 3. Deletion of palladin leads to disrupted cytoskeleton, increased cell proliferation, decreased differentiation apoptosis, and cell adhesion in the developing neural folds. These results may partially explain the causes of NTD in Palladin -/- embryos.
Methods
Mice
Mice containing a heterozygous deletion of palladin were generated previously [17], and maintained on an inbred 129/Sv background under specific pathogen-free (SPF) conditions.
Genotyping
Embryos at E9.5 were collected at somite stage 17–21, embryos at E10.5 were collected at somite stage 32–36. All experiments were performed using somite matched wt and Palladin -/- embryos. Genotype analysis of embryos and adult mice was performed as previously described [17].
Immunofluorescence staining
Embryos were dissected and fixed in 4% paraformaldehyde overnight at 4 °C, dehydrated by sucrose series, then frozen in a Tissue Tek O.C.T. compound (Sakura Finetek, Torrance, CA), and processed to generate 10 μm frozen sections. For immunofluorescence staining, sections were treated with frozen absolute acetone for 10 min, air dried, washed with PBS and blocked with 10% normal goat serum (Jackson ImmunoResearch Laboratories) in 5% BSA/PBS for 15 min at room temperature. After incubation overnight at 4 °C with primary antibodies listed in Additional file 4: Table S1, fluorescently labeled secondary antibodies (Invitrogen) were then used and incubated for 1 h at room temperature. After antibody staining, sections were counterstained with DAPI and mounted with fluorescent mounting medium (Dako). Imaging was performed on a Nikon Eclipse 80i.
Neural progenitors preparation
E10.5 embryonic telencephalons were microscopically dissected to separate the neuroepithelium from the mesenchyme and non-neural ectoderm. The tissue was triturated and trypsinized into single-cell suspension. Single cells were then cultured in DMEM/F-12 medium, a neural progenitor culture medium, containing 20 ng/ml EGF (R&D systems) and 20 ng/ml bFGF (R&D systems) to maintain the pluripotency. Neural progenitor cells were identified by immunofluorescence with an antibody against Nestin.
Whole mount in situ hybridization (WISH)
WISH probes corresponding to the open reading frame were performed as previously described [25]. WISH was performed according to a standard procedure with optimization [25]. Briefly, embryos were dissected and fixed in 4% paraformaldehyde overnight at 4 °C, dehydrated and rehydrated through a graded methanol series. Embryos were then permeabilized with 10 μg/ml proteinase K in PBS for 30 min at room temperature, hybridized with 1 μg/ml digoxigenin (DIG)-UTP-labeled antisense or sense riboprobes at 68 °C. After hybridization, embryos were washed and incubated with blocking reagent for 1 h at room temperature, and then incubated with Anti-DIG-AP Conjugate (Roche) overnight at 4 °C. Signals were detected using a DIG Nucleic Acid Detection Kit (Roche). Images were taken using a Nikon SMZ 800. Primer pairs for Palladin isoform 2 are: sense primer: CACACACTCGGCGCACACGC; antisense primer: CAACTGGGCACCAAATACGC.
TUNEL assay
Apoptotic cells on sections were detected using an In Situ Cell Death Detection Kit (Roche) according to the manufacturer’s protocol. Images were taken with a Nikon fluorescent microscope.
Quantitative RT-PCR (qRT-PCR)
Total RNA was extracted from E9.5 and E10.5 embryonic brains using TriPure Isolation Reagent (Roche) according to the manufacturer’s instructions. The RNA was immediately reverse transcribed into cDNA using PrimeScript RT reagent kit (Takara) according to the manufacturer’s protocol. The process was performed under the following conditions: 37 °C for 15 min, followed by 85 °C for 5 s. SYBR Premix Ex Taq (Takara) was used for qRT-PCR with gene specific primers that amplified across exon-exon junctions. qRT-PCR was performed on an ABI Fast 7500 using the cycling conditions: 95 °C for 30 s, followed by 40 cycles of 95 °C for 5 s, 60 °C for 30 s. The transcript numbers were determined from the linear regression of the standard curves. Each qRT-PCR was performed in triplicate with normalization to Gapdh expression level.
Western blot analysis
Embryonic brains were dissected and treated with radio immunoprecipitation assay (RIPA) lysis buffer (1% Nonidet P-40, 0.1% SDS and 0.5% sodium deoxycholate in PBS) with protease inhibitors mixture (Sigma). The protein concentration was assayed by BCA protein assay kit (Thermo). 50 μg of proteins were separated by SDS/PAGE. The following antibodies and dilutions were used: anti-Cyclin E polyclonal antibody (1:500, Santa cruz), anti-α-actinin monoclonal antibody (1:800, Sigma-aldrich), and anti-GAPDH monoclonal antibody (1:500, Santa cruz). The membranes were incubated with secondary antibodies (LI-COR), and then scanned with the LI-COR Odyssey imaging system.
Cumulative BrdU Assay
Cumulative BrdU labeling in E10.5 embryos was performed as previously described [26, 27]. Briefly, pregnant female mice were intraperitoneally injected with BrdU (1 mg BrdU per 20 g body weight). A series of repeated BrdU injection was performed at an interval of two hours with the following time points: 30 min, 2 h 30 min, 4 h 30 min, 6 h 30 min, and 8 h 30 min. Embryos (n = 5 at each time point) were fixed 30 min after the last injection, and processed to generate frozen sections. Samples were then treated with 2 N HCl at 37 °C for 30 min, washed with PBS, incubated with 20 μg/ml proteinase K for 10 min at room temperature, and treated with 0.1% Triton X-100 for 10 min at room temperature for cell permeabilization. Treated sections were incubated with an anti-BrdU antibody at 4 °C overnight. Signals were detected using an Alexa Fluor 488 conjugated antibody. The proportion of BrdU positive nuclei of neural progenitors was used to calculate Tc (total cell-cycle length) and Ts (S phase) as previously described [26].
Statistical analysis
The Student’s t test was used for statistical analyses. Standard deviation was used to measure deviation from the mean, for all experiments. For all of the statistical tests, p values less than 0.05 were considered statistically significant.
Results
Palladin deficient embryos exhibited severe cranial NTD
We have previously constructed palladin knockout mice. Palladin -/- embryos showed severe cranial NTD and died before E15.5 [17]. To further understand why palladin disruption causes cranial NTD, we collected embryos at E9.5 when Palladin -/- embryos can be distinguished from wt littermates by their failure to close the cranial neural tube. We found that cranial neural tube closure 1 initiated normally in Palladin -/- embryos, yet closure 2 and closure 3 could not occur. Therefore they displayed complete exencephaly from forebrain to hindbrain (Fig. 1A).
The embryonic central nervous system (CNS) is patterned along its left-right, dorsal-ventral, and antero-posterior axes [28]. Neural patterning is the process that provides regional identities in neural cells in accordance with their location in the neural tube. In order to investigate whether palladin deficiency impairs the neural patterning process, we used a brain mesenchyme molecular marker Twist and a fore/midbrain molecular marker Otx2 to examine the development of certain parts of embryonic brain [29, 30]. The expression pattern of these two molecules was not obviously altered in Palladin -/- embryos at E9.5 (Additional file 1: Figure S1).
Palladin was located predominantly in the neural folds at E9.5
We have previously determined that in E8.5 mouse embryo, palladin was mainly expressed in neural plate, while in E9.5 and E10.5 embryos, it showed ubiquitous expression [17]. However, the specific cell types in embryo where each isoform is expressed remain obscure. There are at least five palladin isoforms that produce proteins in mice due to alternative splicing and different promoter usage: isoform 1 encodes a 200 kDa protein, isoform 2 encodes a 140 kDa protein, isoform 3 and 4 encode 90–95 kDa proteins, isoform 5 encodes a 50 kDa protein [31]. Isoform 2 is the major isoform in mice brain. To identify the specific palladin isoforms that expressed in E9.5 mouse brains, we extracted total mRNA from E9.5 wt brains and conducted qRT-PCR using isoform-specific primers. Isoform 2 was detected to express at much higher level than the other four isoforms (Additional file 2: Figure S2). To further characterize the expression pattern of isoform 2 during cranial NTC at E9.5, WISH on E9.5 wt embryos were performed. Embryos were then processed to generate 10 μm frozen sections. We found that the expression of Palladin isoform 2 was restricted to the neural tube, with no expression detected in mesenchyme or non-neural ectoderm (Fig. 1B). Considering the complete exencephaly phenotype observed in Palladin -/- embryos, combined with the neural folds expression pattern of palladin, it would be reasonable to hypothesize that palladin might affect cranial NTC by regulating neural folds behavior. In order to confirm this hypothesis, we examined major cellular events that are essential for neural epithelium during cranial NTC. Cellular events have been inspected included cytoskeleton, proliferation, differentiation, apoptosis and adhesion.
Cytoskeleton architecture was disturbed in palladin deficient neural folds and cultured neural progenitors
Palladin is an actin cytoskeleton-associated protein. We have previously reported that palladin deficiency resulted in weakened actin stress fibers in mouse embryonic fibroblast (MEF) cells [17]. It is possible that cytoskeleton architecture in Palladin -/- neural folds might be affected. To verify this speculation, transverse cryosections at the presumptive mid/hindbrain region from wt and Palladin -/- embryos at E9.5 were stained with an F-actin marker FITC-phalloidin to visualize actin stress fibers. The actin stress fibers (phalloidin positive) in Palladin -/- neural tube were obviously fainter than those in somite matched wt counterpart (Fig. 2A, a and b). We also stained these sections with an antibody against cytoskeleton marker P-cofilin to confirm this observation. Conformably, actin cytoskeleton architecture was more obscure in Palladin -/- neural tube compared with wt neural tube (Fig. 2A, c and d).
To determine the phenotype of cytoskeleton in Palladin -/- neural tube in vitro, neural progenitors taken from E10.5 embryonic neuroepithelium were prepared and subjected to immunostaining with Nestin (a neural stem cell and neural progenitor marker). Results showed that both wt and Palladin -/- neural progenitors were more than 98% Nestin positive (Fig. 2A, e and f), which confirmed they were truly neural progenitors. Neural progenitors were then stained with FITC-phalloidin. F-actin showed a significant decrease in E10.5 Palladin -/- neuroepithelium-derived neural progenitors, compared to that in wt neural progenitors (Fig. 2A, g and h).
In order to understand the mechanism behind the decreased cytoskeleton in Palladin -/- neural tube, total RNAs were extracted from E9.5 wt and Palladin -/- embryonic brains, and reverse transcribed into cDNAs. The mRNA expression of cytoskeleton related proteins which can interact with palladin were then detected in these two genotypic cDNAs by qRT-PCR. Genes have been detected included α-actinin, Argbp2, Eps8, VASP, AKT1, Profilin, LASP1, Clp36, Spin90, Ezrin, ILKAP, LPP and Src [20,32,33,34,35,36,37,38,39,40,, 31–41]. The expression of both α-actinin and Argbp2 showed a significant decrease in Palladin -/- embryonic brain-derived cDNAs compared to that in wt cDNAs (Fig. 2B-C). mRNA levels of Eps8, VASP, AKT1, Profilin, LASP1, Clp36, Spin90, Ezrin, ILKAP, LPP and Src showed no remarkable difference between wt and Palladin -/- brain at E9.5 (Additional file 3: Figure S3A). To confirm this finding, proteins from wt and Palladin -/- embryonic brains were prepared to perform western blot assay, α-actinin was remarkably down-regulated in Palladin -/- embryonic brains (Fig. 2D). The decreased expression of these two genes may contribute to the disturbed cytoskeleton in Palladin -/- neural tube.
Loss of palladin resulted in increased proliferation and abnormal differentiation in neural folds
Cytoskeleton-associated proteins play a role in cell proliferation [42]. Previous studies noted that proper proliferation of neural progenitor cells is critical to NTC [43]. The observation that Palladin -/- embryos displayed NTD suggested that proliferation might be disrupted in Palladin -/- embryos. Therefore, transverse cryosections from wt and Palladin -/- embryos at E9.5 and E10.5 were stained with antibodies against phosphorylated-histone H3-Ser10 (PH3, a M phase marker, marking mitotic cells) and Ki67 (a late G1-M phase marker, marking all dividing cells). For PH3 staining, the number of PH3-positive cells was greatly increased in the region of neural tube at both E9.5 and E10.5 (Fig. 3A, a, b, e and f). PH3-positive cells in the neural tubes were quantitated for 3 sections of each embryo (five embryos from each genotype were stained). The average cell number was compared using unpaired two-tailed student’s t test between wt and Palladin -/- neural tube. It led to a significant difference in both E9.5 and E10.5 embryos (Fig. 3B). Results also showed that at E9.5, there were more PH3-positive cells in dorsal than ventral neural tube in wt embryos (Fig. 3A, a). However, in Palladin -/- embryos, the distribution of PH3-positive cells was more uniform between the dorsal and ventral aspect of the cranial neural tube (Fig. 3A, b). At E10.5, when the cranial NTC finished, proliferation was uniform along the dorso-ventral axis in both wt and Palladin -/- embryos (Fig. 3A, e and f). Moreover, at E9.5, PH3-positive cells specifically distributed at the first layer of neural epithelium at the duct edge in wt neural tube, while they could also been seen in the more internal area in Palladin -/- neural tube (arrows in Fig. 3A, a and b). The abnormal proliferation showed in Palladin -/- embryos was confirmed by Ki67 staining. Proliferation was enormously increased in Palladin -/- neural tube at both E9.5 and E10.5 (Fig. 3A, c, d, g and h).
The development of the nervous system is a very complicated process. It is not only spatially but also temporally regulated, depending on the production of functionally diverse neuronal cell types at their proper locations. Differentiation and proliferation of neural epithelium are related and interdependent. Considering the abnormally increased proliferation in Palladin -/- embryos, we speculated that differentiation might be disrupted. Therefore, we stained embryos at E9.5 and E10.5 with antibody against TuJ1 (also know as beta III Tubulin, a neuronal differentiation marker). At E9.5, in the ventral side of wt neural tube, neural progenitors began to exit the cell cycle, and gradually differentiate into neurons and glial cells, while no differentiation could be seen in Palladin -/- embryos at the same domain (Fig. 3A, c and d). Instead, differentiation was observed in the dorsal half of the neural tube in Palladin -/- embryos, which was not obvious in wt embryos (Fig. 3A, c and d). Interestingly, the area with decreased differentiation in the ventral side of neural tube was corresponding to the region of abnormally increased proliferation in Palladin -/- neural tube. Moreover, at E10.5, with more proliferation in Palladin -/- than wt embryos, differentiation declined in Palladin -/- embryos compared with wt counterparts (Fig. 3A, g and h). This unique correlated pattern of proliferation and differentiation is a confusing issue.
Decreased cell-cycle length in palladin deficient neural progenitors
In order to further elucidate the defects of increased proliferation and decreased differentiation, cryosections from E10.5 wt and Palladin -/- embryos were stained with antibodies against Sox9 (a neural progenitor marker) and P27 (a differentiated neuron marker). The number of Sox9 positive cells and P27 positive cells in the ventral side of neural tube was quantitated respectively to represent the neural progenitors and the differentiated neurons. Results showed neural progenitors increased and differentiated neurons decreased in Palladin -/- neural tube (Fig. 3C). The ratio of proliferating neural progenitors to differentiated neurons was more than 2-fold increased in Palladin -/- embryos than that in wt controls (Fig. 3D). Also qPCR analysis of neural progenitor genes Sox9, Nestin and Pax6 and differentiation genes MAP2, Olig2 and Neurogenin2 was performed to address the phonotype of increased proliferation and decreased differentiation, it turned out that the expression of Sox9 increased in Palladin -/- embryos (Additional file 3: Figure S3B).
Change in cell proliferation is often related to a change in cell cycle length. Embryonic cell cycle process is mediated by cyclins, cyclin-dependent kinases (cdks) and cyclin-related proteins [44]. In order to verify whether the increase of neural progenitors in E10.5 Palladin -/- neural tube was due to a shortened cell cycle length, we first examined the expression of cyclin E (a key positive regulator of cell cycle phase G1/S), by western blotting on embryonic brain proteins from E10.5. Cyclin E showed a significant increase in Palladin -/- embryonic brain (Fig. 4A). Cdk2 (a cyclin E binding partner) was up-regulated and wee1 (a negative regulator of phase G1/S) was down-regulated in E10.5 Palladin -/- brain, determined by qRT-PCR of E10.5 embryonic brain cDNA (Fig. 4B-C). Expression of Cyclin A, Cyclin B and Cyclin D1 was also addressed by qRT-PCR, it showed no significant change in Palladin -/- brain (Additional file 3: Figure S3C). This data suggested a shortened G1/S length in cell cycle of neural progenitors in Palladin -/- embryos. To verify this speculation, a cumulative BrdU incorporation study was performed. At all the five time points, the proportion of BrdU positive cells was significantly higher in Palladin -/- neural tube than that in wt neural tube (Fig. 4D). In wt cranial neural tube, the total cell cycle length minus S phase length was 7.95 h, whereas in Palladin -/- siblings it was shortened to 6.83 h (Fig. 4E).
Decreased apoptosis in neural folds after palladin disruption
Apoptosis plays an important role in NTC, tips of dorsal neural folds undergo apoptosis process so that the neural folds can bend and both ends can meet and fuse [45]. To investigate whether NTD in Palladin -/- embryos was related to a change in apoptosis in the neural fold region, TUNEL assay was performed on E9.5 cryosections. It revealed that Palladin -/- neural folds had a lower level of apoptotic cells compared with that in wt neural folds (Fig. 5A). TUNEL positive cells were quantitated, and there was a significant decrease in Palladin -/- neural tube (Fig. 5B). To confirm this finding, IHC for the antibody of caspase 3 was performed. It turned out a reduction in Palladin -/- neural tubes (Fig. 5C).
To further explore the mechanism of decreased apoptosis, we detected key regulators of cell apoptosis by qRT-PCR on E9.5 embryonic brain cDNAs. Genes have been detected included Bcl2, Bcl-xl, Bad and Bax. Bcl2, a negative regulator of apoptosis, was significantly increased in Palladin -/- embryos (Fig. 5D, Additional file 3: Figure S3D).
Reduced cell adhesion in Palladin -/- neural tubes
Cell adhesion is another important factor that regulates NTC. During the NTC process, after the formation of dorsolateral hinge point (DLHP), neural epithelium migrate from the lateral aspects of the neural tube towards the midline, neural folds then fuse at their dorsal tips to generate a closed neural tube [45]. We have previously observed that MEFs lacking of palladin showed decreased adhesion to fibronectin compared to wt MEFs [17], so we speculated that cell adhesion in Palladin -/- neural folds would be compromised. To assess whether palladin deficiency impaired cell adhesion on the tips of the neural folds, the expression of E-cadherin (a key component of cell adhesion) was first examined by immunofluorescence staining on E9.5 cryosections. A strong expression of E-cadherin could be detected on the tips of neural folds in both wt and Palladin -/- embryos, showing no significant difference (Fig. 6A).
We previously found that β1-integrin is significantly decreased in Palladin -/- MEFs [46]. Given that integrins are critical for cell adhesion and migration [47, 48], we had reasons to presume that β1-integrin might reduce in Palladin -/- neural tube. We checked the expression of β1-integrin on embryos at E9.5 by immunofluorescence staining, and it turned out to be a decreased β1-integrin in Palladin -/- neural tube (Fig. 6B).
Discussion
Although the function of palladin on actin organization, cancer development and invasion has been described, also molecular associations of palladin have been identified one by one, little is known about the role palladin plays during NTC process. In this paper, we show how palladin regulates NTC in vivo. We found that deletion of palladin causes changes of multiple cellular events which are critical for NTC in the developing neural folds. Actin stress fibers within the neuroepithelium is fainter. Proliferation of neural epithelium is increased. Differentiation of neural progenitors is decreased and abnormal spatially. Apoptosis is decreased. Our results suggest that palladin may regulate NTC by modulating these cellular events in the developing neural folds. Hence a general genetic pathway from palladin to the control of NTC has been established. Moreover, we find expression changes of critical molecules for each cellular events, it is absolutely useful for the establishment of direct biochemical pathway for palladin to control of NTC.
Research on expression analysis of palladin has been described [31], we also have investigated stage- and tissue-specific expression of palladin in early embryos [17], However, no reports indicate the specific cell types palladin is expressed during NTC, which is an important question for the study of palladin in NTC. Therefore, we perform qRT-PCR and WISH, and identify that the expression of palladin is highly restricted to the neural epithelium in the embryonic brain at E9.5. This indicates the particular and crucial role of palladin during NTC process. Therefore, our research focuses on the neural folds from E9.5 to E10.5.
Palladin is a cytoskeleton-associated protein. Research in vitro indicated that palladin plays a critical role in actin organization, our results confirmed this finding in vivo. Cytoskeleton is fundamental for many cellular processes, including cell proliferation and differentiation. Since loss of palladin weakens actin network in the developing neural folds, combined the phenotype of extensive outgrowth of neural epithelium in Palladin -/- embryos, it is an expected finding that proliferation is increased in palladin deficient embryos. Since proliferation is often related to cell cycle, shortened cell cycle length is probably a reason of increased proliferation in neural epithelium, thus the cell cycle length was qualified in vivo by cumulative BrdU assay. It turns out a shorter cell cycle length in palladin deficient neural progenitors, which explains the phenomenon of increased proliferation. A report has showed that down-regulation of palladin enhances cell vitality and proliferation in vitro [49], which confirms our finding. However the mechanism of palladin involving in regulating proliferation and cell cycle has not yet been studied, a better understanding of this field is necessary.
The fates of neural progenitors in the ventral side of neural folds in the early embryogenesis are proliferation and differentiation. Since proliferation is increased in Palladin -/- neural progenitors, it is possible that differentiation in the corresponding location is decreased. To confirm this hypothesis, we quantify the ratio of proliferating neural progenitors to differentiated neurons. It turns out a significant increased ratio in palladin deficient neural tube compared to that of wt. It should be noted that in the dorsal side of neural folds, differentiated neurons is increased in palladin deficient neural tube. This is probably a consequence of disturbed cytoskeleton within the neural tube, by differentiated neurons moving from the ventral side to the dorsal side. There is a report suggests that palladin knockdown may facilitate cell differentiation in vitro [49]. It is commonly accepted that dramatic cytoskeletal changes can trigger skeletal muscle differentiation. However, more research is needed to address whether the function of palladin in regulating differentiation is positive or negative.
In the dorsal side of neural folds, neural epithelium undergoes apoptosis to allow the two ends of neural folds to meet and fuse. However, proliferation is increased along the whole neural tube in palladin deficient embryos. So we examine apoptosis in the dorsal side of neural folds, it turns out a significant decreased apoptosis in palladin deficient neural folds. So far, little is known on the role palladin plays in cell apoptosis. For this reason, more research is needed to complete this field.
In our previous study, palladin plays an important role in regulating cell adhesion either in vivo or in vitro by stabilizing β1-integrin [17, 46]. In addition, other researches confirm this finding [50, 51]. So we examined the expression of β1-integrin in neural tube, and found it decreased slightly in palladin deficient neural tubes. Nevertheless, cell adhesion on the tips of neural folds is found to be normal in palladin deficient mouse embryos. It is possible that in surface ectoderm, the function of palladin in cell adhesion is compensated by other proteins in vivo during mouse NTC. Myotilin and myopalladin are members of the palladin/myotilin/myopalladin family [34]. Therefore, further study is needed to determine whether myotilin and myopalladin can functionally compensate for the loss of palladin in vivo during NTC.
NTC is an extremely complex process during embryogenesis. Other than proliferation, differentiation, apoptosis and adhesion, there are other events involved in NTC process. Correct head mesenchyme behaviors, correct cell division direction of non-neural ectoderm, intrinsic forces in neural plate are important for NTC [1, 52, 53]. Therefore, to better understand the mechanism of palladin regulating NTC, the function of palladin in these events requires further exploration.
Conclusions
In conclusion, our results demonstrate that actin-associated protein palladin plays a role in cell proliferation, differentiation and apoptosis in the developing neural folds to regulate NTC process. Our work provides an evidence that palladin is a cell-cycle regulator spatially and temporally required for the neural epithelium proliferation. We believe our findings are helpful for further study of the function of palladin and a better understanding of the underlying molecular mechanism involved in NTC process.
Abbreviations
- ATRA:
-
All-trans retinoic acid
- CNS:
-
Central nervous system
- DIG:
-
Digoxigenin
- DLHP:
-
Dorsolateral hinge point
- E:
-
Embryonic day
- MEF:
-
Mouse embryonic fibroblast
- NTC:
-
Neural tube closure
- NTDs:
-
Neural tube defects
- SJTUSM:
-
Shanghai Jiao Tong University School of Medicine
- WISH:
-
Whole mount in situ hybridization
References
Yamaguchi Y, Miura M. How to form and close the brain: insight into the mechanism of cranial neural tube closure in mammals. Cell Mol Life Sci. 2013;70:3171–86.
Sullivan-Brown J, Goldstein B. Neural tube closure: the curious case of shrinking junctions. Curr Biol. 2012;22:R574–6.
Copp AJ, Greene ND, Murdoch JN. The genetic basis of mammalian neurulation. Nat Rev Genet. 2003;4:784–93.
Kappen C. Modeling anterior development in mice: diet as modulator of risk for neural tube defects. Am J Med Genet C Semin Med Genet. 2013;163C:333–56.
Massarwa R, Ray HJ, Niswander L. Morphogenetic movements in the neural plate and neural tube: mouse. Wiley Interdiscip Rev Dev Biol. 2014;3:59–68.
Ting SB, Wilanowski T, Auden A, Hall M, Voss AK, Thomas T, Parekh V, Cunningham JM, Jane SM. Inositol- and folate-resistant neural tube defects in mice lacking the epithelial-specific factor Grhl-3. Nat Med. 2003;9:1513–9.
Chu CW, Gerstenzang E, Ossipova O, Sokol SY. Lulu regulates Shroom-induced apical constriction during neural tube closure. PLoS One. 2013;8:e81854.
Ueno N, Greene ND. Planar cell polarity genes and neural tube closure. Birth Defects Res C Embryo Today. 2003;69:318–24.
Pyrgaki C, Liu A, Niswander L. Grainyhead-like 2 regulates neural tube closure and adhesion molecule expression during neural fold fusion. Dev Biol. 2011;353:38–49.
Patterson ES, Waller LE, Kroll KL. Geminin loss causes neural tube defects through disrupted progenitor specification and neuronal differentiation. Dev Biol. 2014;393:44–56.
Harris MJ, Juriloff DM. An update to the list of mouse mutants with neural tube closure defects and advances toward a complete genetic perspective of neural tube closure. Birth Defects Res A Clin Mol Teratol. 2010;88:653–69.
Massarwa R, Niswander L. In toto live imaging of mouse morphogenesis and new insights into neural tube closure. Development. 2013;140:226–36.
Yamaguchi Y, Shinotsuka N, Nonomura K, Takemoto K, Kuida K, Yosida H, Miura M. Live imaging of apoptosis in a novel transgenic mouse highlights its role in neural tube closure. J Cell Biol. 2011;195:1047–60.
Okae H, Iwakura Y. Neural tube defects and impaired neural progenitor cell proliferation in Gbeta1-deficient mice. Dev Dyn. 2010;239:1089–101.
Liu TX, Zhang JW, Tao J, Zhang RB, Zhang QH, Zhao CJ, Tong JH, Lanotte M, Waxman S, Chen SJ, et al. Gene expression networks underlying retinoic acid-induced differentiation of acute promyelocytic leukemia cells. Blood. 2000;96:1496–504.
Parast MM, Otey CA. Characterization of palladin, a novel protein localized to stress fibers and cell adhesions. J Cell Biol. 2000;150:643–56.
Luo H, Liu X, Wang F, Huang Q, Shen S, Wang L, Xu G, Sun X, Kong H, Gu M, et al. Disruption of palladin results in neural tube closure defects in mice. Mol Cell Neurosci. 2005;29:507–15.
Shu RZ, Zhang F, Liu XS, Li CL, Wang L, Tai YL, Wu XL, Yang X, Liao XD, Jin Y, et al. Target deletion of the cytoskeleton-associated protein palladin does not impair neurite outgrowth in mice. PLoS One. 2009;4:e6916.
Hasegawa T, Ohno K, Funahashi S, Miyazaki K, Nagano A, Sato K. CLP36 interacts with palladin in dorsal root ganglion neurons. Neurosci Lett. 2010;476:53–7.
Zhou W, Cui S, Han S, Cheng B, Zheng Y, Zhang Y. Palladin is a novel binding partner of ILKAP in eukaryotic cells. Biochem Biophys Res Commun. 2011;411:768–73.
Goicoechea SM, Bednarski B, Stack C, Cowan DW, Volmar K, Thorne L, Cukierman E, Rustgi AK, Brentnall T, Hwang RF, et al. Isoform-specific upregulation of palladin in human and murine pancreas tumors. PLoS One. 2010;5:e10347.
Henderson-Jackson EB, Helm J, Strosberg J, Nasir NA, Yeatman TJ, Kvols LK, Coppola D, Nasir A. Palladin is a marker of liver metastasis in primary pancreatic endocrine carcinomas. Anticancer Res. 2011;31:2957–62.
Najm P, El-Sibai M. Palladin regulation of the actin structures needed for cancer invasion. Cell Adhes Migr. 2014;8:29–35.
Goicoechea SM, Garcia-Mata R, Staub J, Valdivia A, Sharek L, McCulloch CG, Hwang RF, Urrutia R, Yeh JJ, Kim HJ, et al. Palladin promotes invasion of pancreatic cancer cells by enhancing invadopodia formation in cancer-associated fibroblasts. Oncogene. 2014;33:1265–73.
Wilkinson DG, Nieto MA. Detection of messenger RNA by in situ hybridization to tissue sections and whole mounts. Methods Enzymol. 1993;225:361–73.
Nowakowski RS, Lewin SB, Miller MW. Bromodeoxyuridine immunohistochemical determination of the lengths of the cell cycle and the DNA-synthetic phase for an anatomically defined population. J Neurocytol. 1989;18:311–8.
Kim TH, Goodman J, Anderson KV, Niswander L. Phactr4 regulates neural tube and optic fissure closure by controlling PP1-, Rb-, and E2F1-regulated cell-cycle progression. Dev Cell. 2007;13:87–102.
Altmann CR, Brivanlou AH. Neural patterning in the vertebrate embryo. Int Rev Cytol. 2001;203:447–82.
Dill KK, Thamm K, Seaver EC. Characterization of twist and snail gene expression during mesoderm and nervous system development in the polychaete annelid Capitella sp. I. Dev Genes Evol. 2007;217:435–47.
Puelles E, Acampora D, Lacroix E, Signore M, Annino A, Tuorto F, Filosa S, Corte G, Wurst W, Ang SL, et al. Otx dose-dependent integrated control of antero-posterior and dorso-ventral patterning of midbrain. Nat Neurosci. 2003;6:453–60.
Rachlin AS, Otey CA. Identification of palladin isoforms and characterization of an isoform-specific interaction between Lasp-1 and palladin. J Cell Sci. 2006;119:995–1004.
Boukhelifa M, Parast MM, Bear JE, Gertler FB, Otey CA. Palladin is a novel binding partner for Ena/VASP family members. Cell Motil Cytoskeleton. 2004;58:17–29.
Ronty M, Taivainen A, Moza M, Otey CA, Carpen O. Molecular analysis of the interaction between palladin and alpha-actinin. FEBS Lett. 2004;566:30–4.
Otey CA, Rachlin A, Moza M, Arneman D, Carpen O. The palladin/myotilin/myopalladin family of actin-associated scaffolds. Int Rev Cytol. 2005;246:31–58.
Ronty M, Taivainen A, Moza M, Kruh GD, Ehler E, Carpen O. Involvement of palladin and alpha-actinin in targeting of the Abl/Arg kinase adaptor ArgBP2 to the actin cytoskeleton. Exp Cell Res. 2005;310:88–98.
Boukhelifa M, Moza M, Johansson T, Rachlin A, Parast M, Huttelmaier S, Roy P, Jockusch BM, Carpen O, Karlsson R, et al. The proline-rich protein palladin is a binding partner for profilin. FEBS J. 2006;273:26–33.
Goicoechea S, Arneman D, Disanza A, Garcia-Mata R, Scita G, Otey CA. Palladin binds to Eps8 and enhances the formation of dorsal ruffles and podosomes in vascular smooth muscle cells. J Cell Sci. 2006;119:3316–24.
Jin L, Kern MJ, Otey CA, Wamhoff BR, Somlyo AV. Angiotensin II, focal adhesion kinase, and PRX1 enhance smooth muscle expression of lipoma preferred partner and its newly identified binding partner palladin to promote cell migration. Circ Res. 2007;100:817–25.
Ronty M, Taivainen A, Heiska L, Otey C, Ehler E, Song WK, Carpen O. Palladin interacts with SH3 domains of SPIN90 and Src and is required for Src-induced cytoskeletal remodeling. Exp Cell Res. 2007;313:2575–85.
Maeda M, Asano E, Ito D, Ito S, Hasegawa Y, Hamaguchi M, Senga T. Characterization of interaction between CLP36 and palladin. FEBS J. 2009;276:2775–85.
Chin YR, Toker A. The actin-bundling protein palladin is an Akt1-specific substrate that regulates breast cancer cell migration. Mol Cell. 2010;38:333–44.
May SF, Peacock L, Almeida Costa CI, Gibson WC, Tetley L, Robinson DR, Hammarton TC. The Trypanosoma brucei AIR9-like protein is cytoskeleton-associated and is required for nucleus positioning and accurate cleavage furrow placement. Mol Microbiol. 2012;84:77–92.
Yang SL, Yang M, Herrlinger S, Liang C, Lai F, Chen JF. MiR-302/367 regulate neural progenitor proliferation, differentiation timing, and survival in neurulation. Dev Biol. 2015;408:140–50.
Murray AW, Kirschner MW. Cyclin synthesis drives the early embryonic cell cycle. Nature. 1989;339:275–80.
Pai YJ, Abdullah NL, Mohd-Zin SW, Mohammed RS, Rolo A, Greene ND, Abdul-Aziz NM, Copp AJ. Epithelial fusion during neural tube morphogenesis. Birth Defects Res A Clin Mol Teratol. 2012;94:817–23.
Liu XS, Luo HJ, Yang H, Wang L, Kong H, Jin YE, Wang F, Gu MM, Chen Z, Lu ZY, et al. Palladin regulates cell and extracellular matrix interaction through maintaining normal actin cytoskeleton architecture and stabilizing beta1-integrin. J Cell Biochem. 2007;100:1288–300.
Jokinen J, Dadu E, Nykvist P, Kapyla J, White DJ, Ivaska J, Vehvilainen P, Reunanen H, Larjava H, Hakkinen L, et al. Integrin-mediated cell adhesion to type I collagen fibrils. J Biol Chem. 2004;279:31956–63.
Shafaq-Zadah M, Gomes-Santos CS, Bardin S, Maiuri P, Maurin M, Iranzo J, Gautreau A, Lamaze C, Caswell P, Goud B, et al. Persistent cell migration and adhesion rely on retrograde transport of beta(1) integrin. Nat Cell Biol. 2016;18:54–64.
Nguyen NU, Liang VR, Wang HV. Actin-associated protein palladin is required for migration behavior and differentiation potential of C2C12 myoblast cells. Biochem Biophys Res Commun. 2014;452:728–33.
Wan HT, Mruk DD, Li SY, Mok KW, Lee WM, Wong CK, Cheng CY. p-FAK-Tyr(397) regulates spermatid adhesion in the rat testis via its effects on F-actin organization at the ectoplasmic specialization. Am J Physiol Endocrinol Metab. 2013;305:E687–99.
Tay PN, Tan P, Lan Y, Leung CH, Laban M, Tan TC, Ni H, Manikandan J, Rashid SB, Yan B, et al. Palladin, an actin-associated protein, is required for adherens junction formation and intercellular adhesion in HCT116 colorectal cancer cells. Int J Oncol. 2010;37:909–26.
Schoenwolf GC, Smith JL. Mechanisms of neurulation: traditional viewpoint and recent advances. Development. 1990;109:243–70.
Levine AJ, Brivanlou AH. Proposal of a model of mammalian neural induction. Dev Biol. 2007;308:247–56.
Acknowledgments
We thank Dr. Da Fu for critical comments and helpful suggestions on this manuscript.
Funding
This work was partially supported by grants from the National Natural Science Foundation of China (81430028), the Ministry of Science and Technology of China (2011BAI15B02), the grants from the Science and Technology Commission of Shanghai municipality (15DZ2290800, 14ZR1425500, and 13DZ2280600), and the E-Institutes of Shanghai Municipal Education Commission (E03003).
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Authors’ contributions
JT performed most of the experiments in the paper, including most of the immunofluorescence staining experiments, many of the whole mount in situ hybridization experiments and western blotting experiments, and all of the neural progenitors preparation and the cumulative BrdU assay; XC performed the genotyping, qRT-PCR and some of the immunofluorescence staining experiments; LT performed some of the whole mount in situ hybridization experiments; SL performed some of the western blotting experiments; WW performed all of the frozen sectioning experiments; ZW and JT designed the study; ZW directed the study, and obtained the funding; JT drafted the manuscript; CS and HZ revised of the manuscript; YK and JF directed the study. All authors read and approved the final manuscript.
Competing interests
The authors declare that they have no competing interests.
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Animal care and handling was performed as Institutional Animal Care and Use Committee guidelines. Animal studies were conducted under protocols approved by the Animal Ethics Committee of Rui-Jin Hospital affiliated to SJTUSM.
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Additional files
Additional file 1: Figure S1.
Neural patterning is normal in Palladin -/- embryos. Whole mount and section ISH of wt and Palladin -/- embryos for Twist and Otx2 at E9.5. (A) Twist is located in the head mesenchyme region in both wt (a, c, e) and Palladin -/- embryos (b, d, f). (B) Otx2 is located in the forebrain and midbrain region in both wt (a, c, e) and Palladin -/- embryos (b, d, f). The boxed regions in c and d are shown at higher magnification in e and f. (TIF 7155 kb)
Additional file 2: Figure S2.
Palladin isoform 2 is the main isoform expressed in E9.5 mouse brain. Detection of Palladin isoforms in E9.5 wt mouse brain by qRT-PCR using isoform-specific primers. Palladin isoform 2 is the main expressing isoform. Isoform 3 and 4 were detected in a much lower expression level. Isoform 1 and 5 were barely detected. (TIF 284 kb)
Additional file 3: Figure S3.
mRNA level changes in Palladin -/- brain. mRNA levels of Eps8, VASP, AKT1, Profilin, LASP1, Clp36, Spin90, Ezrin, ILKAP, LPP and Src showed no remarkable difference between wt and Palladin -/- brain at E9.5 (A). mRNA levels of neural progenitor genes Sox9, Nestin and Pax6 and differentiation genes MAP2, Olig2 and Neurogenin2, expression of Sox9 increased in Palladin -/- embryos at E10.5 (B). Expression of Cyclin A, Cyclin B and Cyclin D1 showed no significant change in Palladin -/- brain at E10.5 as assayed by qPCR (C). mRNA expression of BCL-XL, Bax and Bad in wt and Palladin -/- embryonic brains. They show no significant differences between wt and Palladin -/-. Error bars indicate SEM; *P < 0.05. (TIF 1172 kb)
Additional file 4: Table S1.
Antibody list. (DOCX 57 kb)
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Tan, J., Chen, XJ., Shen, CL. et al. Lacking of palladin leads to multiple cellular events changes which contribute to NTD. Neural Dev 12, 4 (2017). https://doi.org/10.1186/s13064-017-0081-6
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DOI: https://doi.org/10.1186/s13064-017-0081-6