Background
Interleukin-1beta (IL-1β), one of the most widely studied proinflammatory cytokines, is expressed at high levels in the brain during prenatal and postnatal development and declines to low constitutive levels in the adult [
1,
2], suggesting its important role in brain development. Mounting evidence shows that exposure to environmental insults as well as other adverse events during brain development, such as brain injury, infection and stress, can cause some neurodevelopmental disorders, such as cortical dysplasia [
3]. IL-1β can be significantly activated in the central nervous system (CNS) by these injuries [
4]. Elevated levels of IL-1β in the circulation shortly after preterm birth are also associated with increased risk of neurodevelopmental disorders [
5]. This evidence indicates that dysfunction of IL-1β signaling might be involved in the pathogenesis of some neurodevelopmental disorders.
Previous studies showed that IL-1β can regulate the migration of many types of cell, such as smooth muscle cells [
6], tumor cells [
7], airway epithelial cells [
8], neutrophil [
9] and astrocyte progenitors [
10]. Our pilot experiment revealed that IL-1β was able to attract the migration of cultured cortical neurons. Neuronal migration is an important feature of the cortical development stage, during which postmitotic neurons migrate away from the ventricular zone along radial glial fibers and toward the surface of the cortical plate. Once disturbance of normal migration occurs, neurons may accumulate in unusual areas (heterotopias), resulting in either focal neuronal heterotopias (nodular heterotopias) or diffuse band heterotopias in the white matter (pachygyrias/lissencephalies, double cortex syndrome) [
11]. Thus, studies of whether IL-1β regulates neuronal migration are important to further our understanding of brain development and the pathogenesis of some neurodevelopmental disorders.
In this study, we first investigated the effect of IL-1β on neuronal migration in vitro by using a transwell migration assay and growth cone turning assay. Then we applied RNAi technology combined with in utero electroporation to demonstrate that IL-1β can guide the radial migration during development of the rat neocortex.
Methods
Animals
All pregnant Sprague–Dawley rats used in the present study were provided by the Fourth Military Medical University Animal Center (Xi’an, China) and SLAC Laboratory Animal Co. Ltd (Shanghai, China). The rats were housed under controlled temperature and light conditions (12-hour light/dark cycle with lights on at 8:00 AM), with ad libitum access to food and water. The day at which a vaginal plug was detected was designated embryonic day 0 (E0). All experimental procedures involving rats were in strict accordance with the guidelines established by the US National Institutes of Health (NIH) and were approved by the Fourth Military Medical University Animal Care Committee. Procedures for in utero electroporation and growth cone turning assay were approved by the Animal Care and Administration Committee of the Institute of Neuroscience, Shanghai Institute for Biological Sciences, Chinese Academy of Sciences.
Cell culture and immunocytochemistry
Primary culture of cerebral cortical neurons was performed in accordance with previous methods [
12]. Briefly, cortical tissues from E16 rats were dissected and digested by 0.125% trypsin in phosphate-buffered saline (PBS), and dissociated neurons were plated into 35 mm dishes coated with 100 mg/mL poly-D-lysine. In transfection experiments, cells were transfected with 3 μg of different plasmids by using the Amaxa Nucleofector kit (Amaxa GmbH, Cologne, Germany) following the protocol provided by the manufacturer.
For the detection of IL-1R1 expression
in vitro, cultured cortical neurons at five day
in vitro (DIV) were fixed with 4% paraformaldehyde. Then, double immunofluorescence staining with anti-IL-1R1 (polyclonal antibody, Abcam, Cambridge, UK, 1:100) and anti-Tuj1 (polyclonal antibody, Millipore, Bilerica, MA, USA, 1:1000) was performed according to the protocol described previously [
13]. The specificity of immunolabeling was verified by controls in which the primary antibody was omitted.
Cell migration assay
Migration of dissociated primary cortical neurons was assayed by using a Boyden transwell system (8 μm pore size; Corning Costar, NY, USA) as described previously [
14]. Before seeding, both sides of the transwell were coated overnight with poly-D-lysine (30 μg/mL, Sigma-Aldrich, Saint Louis, MO, USA). Serum-free medium, 250 μl, (neurobasal medium, 2% B27, Gibco, Carlsbad, CA, USA) containing dissociated cells (2 × 10
5 cells per well) was added to the upper insert of a chamber with or without any other reagents. In the bottom chamber, 750 μl of serum-free medium (Neurobasal medium, 2% B27, Gibico) with or without any other reagents was added. Reagents used were IL-1β (PeproTech, London, UK, 0.1 ng/ml, 1 ng/ml, 10 ng/ml) and IL-1RA (R & D, Minneapolis, Minn., USA, 1 ng/ml, 10 ng/ml, 100 ng/ml). Twenty hours after seeding, cells were fixed with 4% paraformaldehyde, and cells attached to the upper side of the membranes were thoroughly scraped off. Cells attached to the bottom side of the membranes were stained with coomassie brilliant blue. Cells were counted from five randomly chosen fields (magnification, × 200) for each membrane under the microscope. Each experiment was repeated at least four times.
Growth-cone turning assay
Cerebellar tissues from Sprague–Dawley rats (Postnal day (P) 0 to P2) were incubated in 0.1% trypsin (Sigma) in PBS for 10 minutes at 37°C, followed by trituration. Dissociated cells were resuspended and plated on coverslips coated with laminin (25 mg/ml; Sigma) and were used for experiments 18 to 24 hours after plating at room temperature (20 to 22°C). Quantitative assay of growth cone turning was performed according to a method described previously [
15]. The pipette tip (1 μm opening) containing the chemical was placed 100 μm away from the center of the growth cone of an isolated neuron and at an angle of 45° with respect to the initial direction of neurites (indicated by the last 10 μm segment of the neurite). A standard pressure pulse of 3 psi was applied at a frequency of 2 Hz with durations of 20 ms. The turning angle was defined by the angle between the original direction of neurite extension and a straight line connecting the positions of the growth cone at the onset and the end of the one-hour period. Neurite extension was quantified by measuring the entire trajectory of net neurite growth over the one-hour period. Only those growth cones with net extension >10 μm over the one-hour period were included for analysis of turning angles. Data are presented as mean ± standard error of the mean (SEM). Statistical significance was analyzed by Kolmogorov–Smirnov test.
Plasmid construction
The IL-1R1-siRNA sequences were designed using an online design tool (
http://dharmacon.gelifesciences.com) and cloned into a pSuper vector under the control of H1 promoter. The siRNA sequences are given as follow:
IL-1R1-RNAi1 (IL-1R1-i1): 5′-GCTGTCCTCTTACTCCAAA-3′;
IL-1R1-RNAi2 (IL-1R1-i2): 5′-GGAGACACACTTACCACTT-3′;
Scramble control (Scramble): 5′-CAGTCGCGTTTGCGACTGG-3′.
To construct the overexpression plasmid of the RNAi-resistant human IL-1R1 homologue (h-IL-1R1), full-length human IL-1R1 was amplified by PCR using primers IL-1R1 hFW and IL-1R1 hRW from human muscle cDNA (a gift from Dr. Shi) and subcloned into the AscI/XhoIsite of pCAG-IRES-EGFP. The sequences of the primers used are shown in Table
1. All the re-constructed plasmids were verified by sequencing.
Table 1
Sequences of PCR primers for RT-PCR experiments
IL-1β RTFW | 5'-AATGACCTGTTCTTTGAGGCTGAC-3' |
IL-1β RTRW | 5-'CGAGATGCTGC TGTGAGATTTGAAG-3' |
IL-1R1 RTFW | 5'-AGAAACTCAACATACTGCCTCA-3' |
IL-1R1 RTRW | 5'-CAGCCACATTCATCACCATC-3' |
β-actin RTFW | 5'-CGTTGACATCCGTAAAGAC-3' |
β-actin RTRW | 5'-TGGAAGGTGGACAGTGAG-3' |
IL-1R1 hFW | 5'-TTGGCGCGCCATGAAAGTGTTACTCAGACT-3' |
IL-1R1 hRW | 5'-CCGCTCGAGCTACCCGAGAGGCACGTGAG-3' |
Western blotting
Western blotting was performed as described previously [
12,
14]. Briefly, primary cultured neurons were lysed in 0.2 mL of lysis buffer (0.1% sodium dodecyl sulfate, 1% Nonidet P-40, 50 mM N-2-hydroxyethylpiperazine-N-2-ethanesulfonic acid (pH 7.4), 2 mM ethylenediaminetetraacetic acid (EDTA), 100 mM NaCl, 5 mM sodium orthovanadate, and 40 M p-nitrophenyl phosphate) with 1% Protease Inhibitor Mixture Set I (Calbiochem, Hofheim, Germany). The total protein concentration of the samples was measured by using the Bio-Rad RC/DC reagent kit (Bio-Rad Laboratories, Hercules, CA, USA). Samples of the protein (50 μg) were loaded per lane on 12% SDS-polyacrylamide gels and transferred to nitrocellulose membranes. The samples were blocked with 5% non-fat milk in Tris-buffered saline with Tween (TBST) for two hours and incubated over night at room temperature with rabbit-derived polyclonal anti-IL-1R1 antibody (Abcam, USA, 1:1000). As a protein loading control, the samples were also incubated with mouse-derived monoclonal anti-α-tubulin (Sigma, USA, 1:3000). After being washed with PBS, the samples were incubated for one hour with goat anti-rabbit immunoglobulin G (IgG) conjugated to horseradish peroxidase (1:3000, Bio-Rad, USA). The density of western blotting bands was measured with the Image Quant 5.2 software (GE Healthcare Life Sciences) and quantified as previously reported [
12,
14].
In uteroelectroporation
Plasmids were transfected by using
in utero electroporation (IUE) in accordance with previous methods [
12]. Multiparous Sprague–Dawley rats on E16 were anesthetized with 10% chloral hydrate (3.5 ml/kg) intraperitoneally. For electroporation of two vectors, a mixture of EYFP (6 mg/ml) and siRNA (6 mg/ml) constructs was prepared at a ratio of 1:1. Uteruses were exposed, and then 15 to 20 μg of plasmid mixed with Fast Green (2 mg/ml; Sigma) was injected by trans-uterus pressure microinjection into the lateral ventricle of embryos. Next, electric pulses were generated by a pulse generator (BTX T830) and applied to the cerebral wall at five repeats of 60 V for 50 ms, with an interval of 100 ms. In some experiments, bromodeoxyuridine (BrdU; Sigma) was injected at 100 mg/kg intraperitoneally twice every 30 minutes 24 hours after
in utero electroporation.
Embryonic brains were directly removed and fixed with 4% paraformaldehyde, and postnatal brains at appropriate ages were removed and fixed in 4% paraformaldehyde after transcardial perfusion. For fluorescence immunostaining, both fetal and postnatal brains were cryopreserved in optimal cutting temperature (OCT) compound (Sakura Finetek, Torrence, CA, USA). Coronal cryostat sections of 30 μm were cut on a freezing microtome and immediately processed for immunostaining by the following three-step free-floating protocol: blocking of nonspecific antigenic sites in 5% bovine serum albumin plus 0.2% Triton X-100, overnight incubation with primary antibodies, and overnight incubation with secondary antibodies. The primary antibodies used were anti-IL-1R1 (polyclonal antibody, Abcam, 1:100), anti-Tuj1 (polyclonal antibody, Millipore, 1:1000), anti-GFP (polyclonal antibody, Invitrogen, Carlsbad, CA, USA, 1:1000), anti-BrdU (monoclonal antibody, Sigma, 1:200) and anti-Nestin (monoclonal antibody, Abcam, 1:500). Fluorescently conjugated monoclonal or polyclonal IgG Alexa 488 or Alexa 633 (Molecular Probes; Eugene, OR, 1:1,000) were used as secondary antibodies. Images were acquired using an F1000 confocal system (Olympus) and were processed using Adobe Photoshop CS. For comparison of neuron distribution, the number of GFP+ or BrdU+ neurons in each subregion (layers II and III, layers IV--VI, IZ-VZ-WM) was counted to calculate the percentages of neurons in each region.
Statistical analysis
All results are expressed as mean ± SEM. Unless otherwise indicated, one way analysis of variance (ANOVA) followed by a Bonferroni post hoc test was used to assess the statistical difference. Statistical significance was set at P <0.05. Data management and statistical analyses were performed using SPSS (v11.0).
Discussion
It is well established that the proinflammatory cytokine IL-1β is a key mediator of inflammation and stress in the CNS [
23]. Here, we demonstrate a novel function of IL-1β in brain development: (1) IL-1β is able to attract neuronal migration and growth cone turning
in vitro; and (2) IL-1R1-KD impairs radial migration of cortical neurons during brain development. These findings suggest that IL-1β signaling contributes to cortical development by guiding neuronal migration.
Previous studies have provided a clue that inflammatory cytokines might play a role in cell migration. Thus, acute brain lesions with an inflammatory element
in vivo induced a reactive migration of SVZ precursor cells toward the lesion site [
24,
25]. Similarly, the inflammatory process in the brain attracted the migration of transplanted neural precursor cells (NPCs) into the brain and spinal cord white matter [
26]. Our findings further clarify that cortical neurons express IL-1R1 and that the inflammatory cytokine IL-1β can guide the direction of neuronal migration. A recent
in vitro study showed that IL-1β inhibited the proliferation of neural progenitor cells derived from the E16 rat brain through activation of the SAPK/JNK pathway by using a [
3H] thymidine incorporation assay [
27]. We used
in utero electroporation to show that knocking down the expression of IL-1R1 in cortical progenitor cells did not significantly affect the proliferation of progenitor cells during development, although other
in vivo studies revealed that there was an increased proliferation in subventricular adult progenitor cells after various brain injuries that contained inflammatory components [
28,
29]. The reason for the apparent discrepancy of the developing brain between
in vivo and
in vitro studies is currently unknown.
Genetic studies in humans and mice have identified many molecules, deficiencies of which cause defects in neuronal migration [
30]. The X-linked dysgenesis that manifests as lissencephaly in males and subcortical heterotopia in females [
31,
32] has been shown to be due to mutations in the
doublecortin gene that is highly expressed in fetal brain. Paradoxically, genetic deletion of
doublecortin gene in mice does not cause neocortical malformation. Similarly, Semaphorin-3A and Robo4 have been demonstrated to guide radial migration of cortical neurons during development [
14,
33], but Semaphorin-3A -null mice or Robo4 conditional knockout mice do not show obvious defects in cortical layering. These observations may be attributed to the compensatory effects of other guidance factors that play redundant functions during development. Recently,
in utero RNAi has been introduced as an important addition to traditional mouse knockout studies for studying loss-of–function effects during brain development [
34]. Using
in utero electroporation to knock down the expression of IL-1R1 in cortical progenitor cells, we observed disrupted migration of developing cortical neurons, although IL-1R1 null mice are of normal vigor and display no overt phenotypes or behavioral abnormalities [
35]. We further found that co-transfection with h-IL1R1 effectively rescued the down-regulation of IL-1R1 in HEK 293 cells and prevented the migration defects of cortical neurons induced by siRNA. However, we did not verify the overexpression of h-IL1R1 in the triple-transfected GFP-positive cortical neurons by immunofluorescence with anti-IL-1R1 antibodies, which may be a weakness of this study.
Current molecular and genetic studies have greatly expanded our knowledge of brain ontogenesis as well as the genetic mechanism of some neurodevelopment diseases, such as malformations of cortical development (MCD) [
36], but it remains unclear how the epigenetic factors, such as
in utero irradiation, infections, trauma and vascular-ischemic events, cause MCD. The prominent histopathologic features in the brain of patients with MCD include the loss of cortical lamination and neuronal heterotopias [
37], suggesting that an aberrant migration of cortical neurons is an essential pathogenetic element. The present study might provide a novel mechanistic clue between IL-1β signaling and MCD. Since IL-1β upregulation is part of a patterned response that unfolds after a wide range of insults including infection, trauma, depression and stroke [
4], it would become a noticeable target for the prevention of MCD during pregnancy.
Competing interests
The authors declare that they have no competing interests.
Authors’ contributions
LM and XWL performed in utero electroporation experiments, analyzed the data and contributed to the drafting of the manuscript. SJZ performed transwell and growth cone turning assays. FY and GMZ performed western blotting and immunocytochemistry experiments, and analyzed the data. XBY designed the experiments and analyzed data. WJ conceived and designed the experiments, analyzed data and wrote the manuscript. All authors participated in the critical revision of the manuscript for important intellectual content. All authors read and approved the final manuscript.