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Expression of Tbr2 in the Hippocampus Following Pilocarpine-induced Status Epilepticus

Pilocarpine에 의한 경련중첩증 후 해마에서 Tbr2 발현에 관한 연구

  • Choi, Yun-Sik (Department of Pharmaceutical Science and Technology, Catholic University of Daegu)
  • 최윤식 (대구가톨릭대학교 제약산업공학과)
  • Received : 2013.11.07
  • Accepted : 2013.12.11
  • Published : 2013.12.30

Abstract

T-box transcription factor 2 (Tbr2) is a member of the T-box family of transcription factors and it plays an important role in brain development, progenitor cell proliferation, and the modulation of differentiation and function in immune cells, such as CD8+ T cells and natural killer cells. This study aims to elucidate the involvement of Tbr2 in the pathophysiological events following pilocarpine-induced status epilepticus in mice. Status epilepticus resulted in prominent neuronal cell death in discrete brain regions, such as CA3, the hilus, and the piriform cortex. Interestingly, when the immunoreactivity of Tbr2 was examined two days after status epilepticus, it was transiently increased in CA3 and in the piriform cortex. Tbr2-positive cells in CA3 and the piriform cortex were double-labeled with CD11b, a marker of microglia and a subset of white blood cells, such as monocytes, CD8+ T cells, and natural killer cells. Moreover, the double-labeled cells with Tbr2 and CD11b showed amoeboid morphology, and this data indicates that Tbr2-expressing cells may be reactive microglia or infiltrating white blood cells. Furthermore, clustered Tbr2-positive cells were observed in the platelet endothelial cell adhesion molecule-1 (PECAM-1)-positive blood vessels near the CA3 area, which suggests that Tbr2-positive cells may be infiltrating the white blood cells. Based on this data, this study is the first to indicate the involvement of Tbr2 in neuropathophysiology in status epilepticus.

Tbr2는 T-box family 전사인자의 하나로써 뇌의 발달, 전구세포의 증식, 그리고 CD8+ T 세포와 자연살상세포의 분화와 기능에 중요한 역할을 하는 것으로 알려져 있다. 본 연구는 마우스에서 pilocarpine을 이용하여 경련중첩증을 유도한 후 나타나는 병리기전에 Tbr2의 연관성을 확인하였다. 경련중첩증은 해마의 CA3, hilus 그리고 조롱박피질 등에서 뚜렷한 신경세포의 손상을 유발하였다. 흥미롭게도 Tbr2를 이용한 조직 염색에서 경련중첩증 2일 후에 CA3와 조롱박피질에서 면역반응성이 뚜렷하게 증가하는 것을 관찰하였다. 또한 CA3와 조롱박피질에서 Tbr2를 발현하는 세포는 미세아교세포와 단핵구, CD8+ T세포 또는 자연살상세포 등 백혈구의 표지물질인 CD11b 와 이중염색되는 것을 발견하였다. Tbr2와 CD11b에 동시에 염색된 세포는 아메바 모양의 형태를 갖추고 있는 것을 발견하였다. 게다가 혈관 내피세포에서 발혈되는 platelet endothelial cell adhesion molecule-1(PECAM-1)과 이중 염색한 결과 Tbr2를 발현하는 세포가 CA3 지역의 혈관내에 다량 존재하는 것을 확인하였다. 이상의 결과를 종합할 때 Tbr2를 발현하는 세포는 뇌 조직으로 이주하는 백혈구일 가능성이 높음을 보여준다. 이러한 결과는 경련중첩증에 따른 신경병리기전에 Tbr2가 관여할 가능성이 높음을 처음으로 제시하였다.

Keywords

Introduction

The T-box family of transcription factor genes play an important role in early embryonic cell fate decisions, development of extraembryonic structures, embryonic patterning, and organogenesis [21]. Among these genes, T-box transcription factor 2 (Tbr2), also known as eomesodermin (Eomes), comprises the Tbr2 subfamily with Tbr1 and Tbx21 (T-bet), and regulates the differentiation of excitatory projection neurons and retinal ganglion cells [11, 17]. In addition, Tbr2 is required for the maintenance of excitatory-inhibitory balance in the olfactory bulb circuitry [20, 26] and conditional ablation of Tbr2 during development results in the loss of intermediate progenitor cells, decrease in cortical surface expansion, and thickness with neuronal reduction [27]. Furthermore, in adult mouse hippocampus, Tbr2 protein is specifically expressed by intermediate-stage progenitor cells, a type of transit amplifying cells, which respond to neurogenic stimuli, such as voluntary wheel running [12].

Tbr2 is also expressed in a subset of white blood cells, such as CD8+ T cells and natural killer cells. In CD8+ T cells, Tbr2 with T-bet induces the expression of granzyme B, perforin, and interferon-γ (IFN-γ), and both transcription factors are thought to be involved in differentiation of effector and memory T cells [9, 13, 16, 22]. Interestingly, the amount of memory CD8+ T cells decreased when Tbr2 gene was deleted whereas it increased when T-bet was absent [3]. Additionally, Tbr2 expression was promoted by interleukin-2 (IL-2) and Tbr2 expression with T-bet facilitated tumor infiltration by CD8+ T cells [24, 29]. In case of mature natural killer cells, the deletion of Tbr2 causeed reversion to a more immature state and deficiency in both T-bet and Tbr2 resulted in the loss of classical natural killer cell antigens [10]. All these observations indicate that Tbr2 is a critical transcription factor modulating not only early brain development and hippocampal neurogenesis but also the differentiation and function of white blood cells.

Although the role of Tbr2 in the peripheral tissues and during brain development has been well characterized, its role in the central nervous system under pathological conditions, such as status epilepticus (SE) or stroke is not known. SE is a devastating disease, resulting in selective neuronal cell death, microglial reaction, and recurrent seizure [6, 7, 14]. Moreover, blood-brain barrier (BBB) leakage has been reported following pilocarpine-induced SE, which may provide an environment for peripheral leukocyte infiltration. On the other hand, when examined 2 days after SE, pilocarpine-induced SE increased progenitor cell proliferation in the subgranular zone through insulin-like growth factor-1 (IGF-1)-ERK-MSK signaling pathways [4, 5]. Considering the distinct roles of Tbr2 in proliferation and differentiation of progenitor cells as well as in the infiltration of CD8+ T cells and natural killer cells, it may be interesting to investigate the intervention of Tbr2 in progenitor cell proliferation and/or immune reaction following SE. Thus, this study was designed to elucidate the involvement of Tbr2 in the pathophysiological events following pilocarpine-induced SE in mice.

 

Materials and Methods

Animals

Male C57BL/6 mice (8 weeks old, Harlan, Indianapolis, IN) were housed at standard temperature (22±1℃) and humidity (50±1%) levels, and in a light-controlled environment (lights on from 8:00 a.m. to 8:00 p.m.) with ad libitum access to food and water. The animal experiments were conducted in accordance with the National Institutes of Health Guide for the Care and Use of Laboratory Animals (NIH Publication No. 80-23, revised 1996). All efforts were made to minimize animal suffering and to use the minimum number of animals possible.

Pilocarpine-induced status epilepticus and BrdU injection

The mice were initially given an intraperitoneal injection (i.p.) of atropine methyl nitrate (1 mg/kg in saline, Sigma, St. Louis, MO) and 30 min later, SE was elicited by an intra-peritoneal injection (i.p.) of pilocarpine (325 mg/kg in saline, Sigma). SE was defined as a continuous motor seizure persisting for over 3 hr. The control animals were initially injected with atropine methyl nitrate (1 mg/kg) and subsequently with saline, instead of pilocarpine. To label the proliferating cells, 5-bromo-2´-deoxyuridine (100 mg/kg in saline, Sigma) was injected (i.p.) 2 hr before sacrifice.

Tissue processing

The mice were anesthetized with 15% chloral hydrate and transcardially perfused with saline, followed by 4% paraformaldehyde in 0.1 M phosphate buffer (PB), pH 7.4. The brains of the mice were postfixed for 4 hr and subsequently cryoprotected in 30% sucrose in 0.1 M PB. A cryotome was used to prepare sequential coronal sections (30 µm thick) through the hippocampus.

Immunofluorescence

For immunofluorescence labeling, sections were blocked with 10% normal goat serum, followed by overnight incubation with rabbit polyclonal anti-Tbr2 antibody (1:500; Abcam, Cambridge, MA). Next, sections were incubated (2 hr at room temperature) with secondary antibodies conjugated with Alexa 488 and Alexa 594 (1:1,000; Invitrogen, San Diego, CA) and subsequently mounted with Cytoseal (Richard-Allan Scientific, Kalamazoo, MI). For double labeling with BrdU, sections were incubated in 2XSSC/50% formamide for 2 hr at 65℃, followed by incubation in 2 N HCl at 37℃ for 1 hr. After washing with 0.05 M borate buffer (pH 8.5) for 10 min and then washing with PBS, sections were blocked with 10%normal goat serum, followed by overnight incubation with rabbit polyclonal anti-Tbr2 antibody and rat monoclonal anti-BrdU antibody (1:400; Accurate Chemical, Westbury, NY). Sections were incubated (2 hr at room temperature) with secondary antibodies conjugated with Alexa 488 and Alexa 594 (1:1,000). For the visualization of the nucleus, 80 µM Hoechst 33342 (Fluka, Switzerland) was added for 20 min. Fluorescence images were captured using a Zeiss (Oberkochen, Germany) 510 Meta confocal microscope (2-µm-thick optical section).

Cresyl violet staining

In brief, sections were mounted on gelatin-coated slides and dried. After dehydrating in a graded alcohol series, sections were stained (20 min) with 0.1% cresyl violet solution. After destaining with a solution of 95% ethanol and 0.1% glacial acetic acid, sections were dehydrated and mounted with Permount.

 

Results

Selective cell death following pilocarpine-induced status epilepticus

The selective neuronal damage in the hippocampus following pilocarpine-induced SE has been well studied. Previous study shows that neuronal damage can be observed as early as 6 hr post SE in the hilus and later on in CA3 and CA1 [6]. In accordance with these findings, compared to saline-injected control prominent neuronal damage was observed in the hippocampal CA3 and hilus examined at 3 days post SE (Fig. 1). In this study, cresyl violet, which stains viable cells, was used.

Fig. 1.Status epilepticus by pilocarpine injection induces neuronal cell death in the hippocampus. (A) Cresyl violet histology was performed to identify cell viability. In saline-injected control animals, cresyl violet-stained neurons were observed throughout the hippocampus, including the hilus and CA3 regions. (B) Marked cell damage was observed in the CA3 and hilus regions of the hippocampus when examined at 3 days post SE. Boxed areas in the hilus and CA3 are magnified on the right panel. Hil: hilus. Scale bar=200 µm (low magnification image), 100 µm (high magnification image).

Increased expression of Tbr2 in the CA3 area following pilocarpine-induced status epilepticus

Tbr2 expression was examined by immunofluorescence with anti-Tbr2 antibody. As shown in Fig. 2A, under normal conditions, the Tbr2 expression level was minimal in the hippocampus. However, at 2 days after SE, a high density of Tbr2-expressing cells was observed in the CA3 region where prominent neuronal cell death was also observed, and Tbr2 signaling was almost disappeared at 7 days after SE. Pilocarpine-induced SE also caused neuronal loss in the piriform cortex and an emergence of Tbr2-expressing cells at 2 days post SE (Fig. 2B). These spatial and temporal expression profiles may indicate that Tbr2-expressing cells appear in regions that are vulnerable to pilocarpine-induced SE.

Fig. 2.Tbr2 expression in the CA3 and piriform cortex at 2 days post SE. (A) Representative images of Tbr2 (green) in the hippocampus in saline-treated control (Con) animals at 2 days or 7 days post SE. Hoechst staining was used to visualize hippocampal cells. The image shows minimal immunoreactivity in saline-treated control animals. However, marked Tbr2-expressing cells were observed in CA3, and Tbr2-expressing cells almost disappeared at 7 days post SE. The boxed areas in each image are magnified below. Scale bar=250 µm (low magnification image), 50 µm (in A3). (B) Tbr2 expression at 2 days post SE in the piriform cortex. Tbr2 immunoreactive cells were also observed in the piriform cortex at 2 days post SE. In this region, Tbr2 immunoreactive cells were not observed in saline-treated control animals at 7 days post SE. Scale bar=50 µm.

Induction of Tbr2 in CD11b-immunoreactive cells

As mentioned earlier, Tbr2 is a marker of intermediate-stage progenitor cells. Thus, BrdU, a thymidine analogue, was administered to mice to label actively proliferating progenitor cells and the animals were sacrificed 2 hr later. However, as shown in Fig. 3, there were no double-labeled cells with Tbr2 and BrdU in both CA3 and piriform cortex. This indicates that Tbr2-positive cells in CA3 and piriform cortex may not be intermediate-stage progenitor cells.

Fig. 3.Double labeling with Tbr2 and BrdU. Double immunofluorescence labeling with Tbr2 (green) and BrdU (red), a marker of actively proliferating cells, was performed at 2 days post SE. (A) In the CA3 region, there were no double-labeled cells with Tbr2 and BrdU. (B) In the piriform cortex, double-labeled cells with Tbr2 and BrdU were not observed. This data suggests that Tbr2-expressing cells in the CA3 and piriform cortex are not actively proliferating cells. For this study, BrdU was administered to mice at 2 days post SE and the mice were sacrificed 2 hr later. Scale bar=50 µm.

Next, to elucidate the cells that express Tbr2, Tbr2 was double labeled with CD11b, a marker of microglia, monocytes, natural killer cells, and a subset of CD8+ T cells [25]. Surprisingly, as shown in Fig. 4, CD11b-positive cells in CA1 area were not double labeled with Tbr2. On the other hand, a large population of CD11b-positive cells in CA3 and piriform cortex was double labeled with Tbr2. Moreover, the morphology of Tbr2-positive cells was different from that of the Tbr2-negative cells. In CA1 area, CD11b-positive cells have a ramified shape, which is a typical morphological characteristic of inactive microglia. However, double-labeled cells with Tbr2 and CD11b in CA3 and piriform cortex have an amoeboid or round shape, which can be observed in activated microglia and migrating immune cells, such as monocyte, CD8+ T cells, and natural killer cells [15, 28]. Further, even in CA3 and piriform cortex, CD11b-positive cells with ramified morphology do not express Tbr2 (arrows). This information indicates that Tbr2 is expressed in CD11b-positive amoeboid cells in the hippocampal CA3 and piriform cortex, at 2 days post SE.

Fig. 4.Double labeling with Tbr2 and CD11b. Double immunofluorescence labeling with Tbr2 (green) and CD11b (red), a marker of microglia and a subset of white blood cells, such as monocytes, CD8+ T cells, or natural killer cells, was performed at 2 days post SE. (A) In the hippocampal CA1 area, CD11b-positive cells were not colabeled with Tbr2. (B) In the CA3 area CD11b-positive cells were co-labeled with Tbr2. (C) In the piriform cortex, CD11b-positive cells were colabeled with Tbr2. Moreover, double-labeled cells in the CA3 and piriform cortex have amoeboid or round morphology, suggesting reactive microglia or infiltrating white blood cells, such as monocytes, CD8+ T cells, or natural killer cells. Please note the existence of ramified CD11b-positive cells, which are not double-labeled with Tbr2, in CA3 and piriform cortex (arrows). Scale bar=20 µm.

Induction of Tbr2 in infiltrating white blood cells

Considering the distribution and morphology of Tbr2-positive cells, it is conceivable that Tbr2-positive cells are infiltrating white blood cells. To confirm this, Tbr2 was double labeled with PECAM-1. PECAM-1 is constitutively expressed on vascular cells; therefore, it is used as a marker of blood vessels. As shown in Fig. 5, clustered Tbr2-positive cells were observed inside the blood vessels in the CA3 area, with scattered distribution pattern in the parenchyma at 2 days post SE. Taken together, these data strongly suggest that Tbr2-positive cells in hippocampal CA3 region following SE are infiltrating CD11b-positive white blood cells.

Fig. 5.Double labeling with Tbr2 and PECAM-1. Double immunofluorescence labeling with Tbr2 (green) and platelet endothelial cell adhesion molecule-1 (PECAM-1; red), a marker of blood vessels, was performed at 2 days post SE. In the hippocampal CA3 region, clustered Tbr2-positive cells were observed inside the blood vessels labeled PECAM-1. Scale bar=20 µm.

 

Discussion

In this study, the initial and unexpected finding was that Tbr2 is transiently expressed in the hippocampal CA3 region at 2 days after pilocarpine-induced SE. Double immunolabeling with several kinds of markers revealed that Tbr2-expressing cells are CD11b positive. In addition, these double- labeled cells have amoeboid morphology, indicating that they are reactive microglia or infiltrating white blood cells, such as monocytes, CD8+ T cells, or natural killer cells. On the contrary, in the CA1 area, CD11b-positive cells, which were not colabeled with Tbr2, have a ramified shape, indicating resting microglia. Further, clustered Tbr2-positive cells were found in the blood vessels near the CA3 area. This information reveals that Tbr2 is transiently expressed in infiltrating white blood cells in vulnerable brain regions following SE.

Tbr2 shows highly restricted spatiotemporal expression patterns during development. For example, Tbr2 is expressed in multipotent trophoblast stem cells (TSCs) from early postimplantation stages, and Tbr2-positive TSCs constitute the cellular source for the embryonic part of the placenta [23]. In developing neocortex, Tbr2 is upregulated during transition from radial glia to intermediate progenitor cells, which provide neurons of almost all cortical layers [8]. Recently, the function of Tbr2 during early brain development was well characterized by conditional inactivation [1]. Briefly, loss of Tbr2 leads to a reduced number of proliferating cells in the subventricular zone concomitant with markedly reduced brain size, in cortex and olfactory bulbs, but without any influence on apoptosis.

In this study, the major and unexpected finding was that SE induces Tbr2 expression prominently in CA3 and piriform cortex. Previously, it was reported that acute BrdU incorporation (30 min before cervical dislocation) results in ~20% of double-labeled cells with BrdU and Tbr2 among BrdU-labeled cells [8]. Therefore, although hippocampal CA3 and piriform cortex are not known as neurogenic regions in the adult brain, we employed BrdU to label actively proliferating cells, thereby clarified the possibility of Tbr2 expression in intermediate progenitor cells. However, in our study, although the subset of Tbr2-positive cells was co-labeled with BrdU in the subgranular zone (data not shown), there were no double-labeled cells in CA3 and piriform cortex, which suggests that Tbr2-positive cells in CA3 and piriform cortex are not intermediate progenitor cells. Instead, almost all Tbr2-positive cells in CA3 and piriform cortex were CD11b positive. CD11b is a marker of microglia, natural killer cells, and a subset of CD8+ T cells and monocytes. Natural killer cells can be classified into four main developmental stages according to their surface markers; CD11b+CD27+ and CD11b+CD27- natural killer cells are classified as mature cells. In addition, CD8+CD11b+ T cells comprise less than 3% of naïve mouse splenocytes and its population increases with viral infection [18]. Therefore, one potential inference is that CD11b-positive cells in CA3 and piriform cortex could be reactive microglia and/or infiltrating white blood cells such as CD8+ T cells, natural killer cells or monocytes.

Blood-brain barrier (BBB) is the most important vascular structure of the central nervous system. The BBB regulates the trafficking of immune cells and prevents free movement of cytokines between the brain and the blood. Recently, increasing evidences indicate that the intensity of BBB is disrupted by various pathological events, including stroke and SE [2, 19]. In addition, compelling evidence suggests that BBB leakage may be an etiological event contributing to the development of seizure [14]. Interestingly, several independent research findings indicate that although some leukocytes are present in the vicinity of blood vessels after an acute seizure, leukocytes are not observed in the parenchyma [14]. However, whether white blood cells, such as monocytes, CD8+ T cells, or natural killer cells, infiltrate into the brain following SE is still unclear; therefore, further study is required to clarify the identity of Tbr2-expressing cells in CA3 and piriform cortex following SE.

Next, the role of Tbr2 in the brain during inflammation is unknown. In the peripheral tissues, however, Tbr2 is reportedly involved in the function of CD8+ T cells and natural killer cells. Under normal conditions, low, but detectable, levels of Tbr2 mRNA were reported in naïve CD8+ T cells. However, mice infected with lymphocytic choriomeningitis virus showed high levels of Tbr2 mRNA in CD8+ T cells, but low levels of Tbr2 in activated CD4+ T cells [22]. The major function of CD8+ T cells is to lyse target cells by secreting granules containing perforin and granzymes. Interestingly, it was reported that the production of IFN-γ, perforin, and granzyme B in CD8+ T cells and natural killer cells was impaired by the loss of the Tbr2 function, suggesting that Tbr2 plays a critical role in directing the lytic effector differentiation of CD8+ T cells [22]. Similarly, another study indicated that mice with compound mutations in Tbr2 and T-bet were nearly devoid of memory CD8+ T cells and mature natural killer cells [13]. Given the proposed roles played by Tbr2 in peripheral tissues, elucidating the role of Tbr2 in neuronal damage, glial reaction, epileptogenesis, and even leukocyte infiltration following SE will provide a new insight into understanding epileptic events and development of new therapeutic tools.

In summary, this study is the first to reveal the involvement of Tbr2 in pilocarpine-induced SE and further studies will be required to clarify the identity of Tbr2-expressing cells and its role of in neuropathology by SE.

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