Choon Sang Bae

System l-amino acid transporters are differently expressed in rat astrocyte and C6 glioma cells

The system L-amino acid transporter is a major nutrient transport system that is responsible for Na+-independent transport of neutral amino acids including several essential amino acids. We have compared and examined the expressions and functions of the system L-amino acid transporters in both rat astrocyte cultures and C6 glioma cells. The rat astrocyte cultures expressed the l-type amino acid transporter 2 (LAT2) with its subunit 4F2hc, whereas the l-type amino acid transporter 1 (LAT1) was not expressed in these cells. The C6 glioma cells expressed LAT1 but not LAT2 with 4F2hc. The [14C]l-leucine uptakes by the rat astrocyte cultures and C6 glioma cells were Na+-independent and were completely inhibited by the system l selective inhibitor, BCH. These results suggest that the transport of neutral amino acids including several essential amino acids into rat astrocyte cultures and C6 glioma cells are for the most part mediated by LAT2 and LAT1, respectively. Therefore, the rat astrocyte cultures and C6 glioma cells are excellent tools for examining the properties of LAT2 and LAT1, respectively. Moreover, the specific inhibition of LAT1 in cancer cells might be a new rationale for anti-cancer therapy.

Characterization of mouse brain-specific angiogenesis inhibitor 1 (BAI1) and phytanoyl-CoA alpha-hydroxylase-associated protein 1, a novel BAI1-binding protein

Previously, PAHX-AP1 (PAHX-associated protein 1) was isolated as a novel protein to interact with Refsum disease gene product (phytanoyl-CoA alpha-hydroxylase, PAHX) and specifically expressed in mouse brain. PAHX-AP1 is also suggested to be involved in the development of the central neurologic deficits of Refsum disease. To clarify its function, we have searched for proteins that associate with PAHX-AP1 via yeast two-hybrid system. We found that PAHX-AP1 interacts with the cytoplasmic region of human brain-specific angiogenesis inhibitor 1 (hBAI1), and isolated murine homolog of hBAI1. Structural analysis of the PAHX-AP1 with three reported hBAI-associated proteins (BAP) revealed no homology among them, and we designated PAHX-AP1 as BAP4. The ability of BAP4 to interact with BAI1 was confirmed by pulling-down BAI1 with GST-BAP4 protein and immunoprecipitation study using brain lysate. Northern and Western blot analyses demonstrated a unique pattern of BAI1 expression in the brain. The peak level of BAI1 was observed 10 days after birth. In situ hybridization analyses of the brain showed the same localization of BAI1 as BAP4, such as most neurons of cerebral cortex, hippocampus, and V, VI, VII, VIII, and XII nuclei. Because BAI1 possessed thrombospondin-type 1 repeats in its extracellular region, changes of BAI1 expression were examined in the focal cerebral ischemia model. The BAI1 expression decreased on the ischemic side after 24 h but BAP4 was not changed after the time-course of ischemia. Our results indicate that expression and localization of BAI1 in the brain is correlated with BAP4, and that BAI1 is involved in inhibition of angiogenesis and neuronal differentiation.

Expression of brain-specific angiogenesis inhibitor 3 (BAI3) in normal brain and implications for BAI3 in ischemia-induced brain angiogenesis and malignant glioma.

Murine brain‐specific angiogenesis inhibitor 1 and 2 (mBAI1, mBAI2) are involved in angiogenesis after cerebral ischemia. In this study, mBAI3 was cloned and characterized. Northern and Western blot analyses demonstrated a unique developmental expression pattern in the brain. The level of mBAI3 in brain peaked 1 day after birth, unlike mBAI1 and mBAI2, which peaked 10 days after birth. In situ hybridization analyses of the brain showed the same localization of BAI3 as BAI1 and BAI2, which includes most neurons of cerebral cortex and hippocampus. In the in vivo focal cerebral ischemia model, BAI3 expression decreased from 0.5 h after hypoxia until 8 h, but returned to control level after 24 h. The expression of vascular endothelial growth factor following ischemia showed an inverse pattern. The decreased expressions of BAIs in high‐grade gliomas were observed, but BAI3 expression was generally lower in malignant gliomas than in normal brain. Our results indicate that the expression and distribution of BAI3 in normal brain, but not its developmental expression, are very similar to those of BAI1 and BAI2, and that BAI3 may participate in the early phases of ischemia‐induced brain angiogenesis and in brain tumor progression.

Expression of Brain-Specific Angiogenesis Inhibitor 2 (BAI2) in Normal and Ischemic Brain: Involvement of BAI2 in the Ischemia-Induced Brain Angiogenesis:

Previously, the authors cloned and characterized murine brain-specific angiogenesis inhibitor 1 (mBAI1). In this study, the authors cloned mBAI2 and analyzed its functional characteristics. Northern and Western blot analyses demonstrated a unique developmental expression pattern of mBAI2 in the brain. The expression level of mBAI2 appeared to increase as the development of the brain progressed. Reverse transcription-polymerase chain reaction (RT-PCR) analyses demonstrated the existence of alternative splice variants of mBAI2, which were defective in parts of type I repeat of thrombospondin or the third cytoplasmic loop of the seven-span transmembrane domain that were considered essential to the functions of mBAI2. The expressions of spliced variants in the brain were differently regulated compared with wild-type mBAI2 during development and ischemic conditions. In situ hybridization analyses of the brain showed the same localization of BAI2 as BAI1, such as in most neurons of cerebral cortex. In the in vivo focal cerebral ischemia model and the in vitro hypoxic cell culture model with cobalt, BAI2 expression decreased after hypoxia and preceded the increased expression of vascular endothelial growth factor (VEGF). RT-PCR analysis of antisense BAI2 cDNA-transfected SHSY5Y cells showed an increased VEGF expression as well as a decreased BAI2 expression. Immunohistochemical study of focal ischemic cortex showed that the regional localization of decreased BAI2 was related to the formation of new vessels. These results suggest that the brain-specific developmental expression pattern of angiostatic BAI2 is correlated with the decreased neovascularization in the adult brain, and that angiostatic BAI2 participates in the ischemia-induced brain angiogenesis in concert with angiogenic VEGF.

HOXB13 is co-localized with androgen receptor to suppress androgen-stimulated prostate-specific antigen expression.

During the prostate cancer (PCa) development and its progression into hormone independency, androgen receptor (AR) signals play a central role by triggering the regulation of target genes, including prostate-specific antigen. However, the regulation of these AR-mediated target genes is not fully understood. We have previously demonstrated a unique role of HOXB13 homeodomain protein as an AR repressor. Expression of HOXB13 was highly restricted to the prostate and its suppression dramatically increased hormone-activated AR transactivation, suggesting that prostate-specific HOXB13 was a highly potent transcriptional regulator. In this report, we demonstrated the action mechanism of HOXB13 as an AR repressor. HOXB13 suppressed androgen-stimulated AR activity by interacting with AR. HOXB13 did neither bind to AR responsive elements nor disturb nuclear translocation of AR in response to androgen. In PCa specimen, we also observed mutual expression pattern of HOXB13 and AR. These results suggest that HOXB13 not only serve as a DNA-bound transcription factor but play an important role as an AR-interacting repressor to modulate hormone-activated androgen receptor signals. Further extensive studies will uncover a novel mechanism for regulating AR-signaling pathway to lead to expose new role of HOXB13 as a non-DNA-binding transcriptional repressor.

Neuroprotection by Valproic Acid in Mouse Models of Permanent and Transient Focal Cerebral Ischemia

Valproic acid (VPA) is a well-known anti-epileptic and mood stabilizing drug. A growing number of reports demonstrate that VPA is neuroprotective against various insults. Despite intensive efforts to develop new therapeutics for stroke over the past two decades, all treatments have thus far failed to show clinical effect because of treatment-limiting side effects of the drugs. Therefore, a safety-validated drug like VPA would be an attractive candidate if it has neuroprotective effects against ischemic insults. The present study was undertaken to examine whether pre- and post-insult treatments with VPA protect against brain infarct and neurological deficits in mouse transient (tMCAO) and permanent middle cerebral artery occlusion (pMCAO) models. In the tMCAO (2 hr MCAO and 22 hr reperfusion) model, intraperitoneal injection of VPA (300 mg/kg, i.p.) 30 min prior to MCAO significantly reduced the infarct size and the neurological deficit. VPA treatment immediately after reperfusion significantly reduced the infarct size. The administration of VPA at 4 hr after reperfusion failed to reduce the infarct size and the neurological deficit. In the pMCAO model, treatment with VPA (300 mg/kg, i.p.) 30 min prior to MCAO significantly attenuated the infarct size, but did not affect the neurological deficit. Western blot analysis of acetylated H3 and H4 protein levels in extracts from the ischemic cortical area showed that treatment with VPA increased the expression of acetylated H3 and H4 at 2 hrs after MCAO. These results demonstrated that treatment with VPA prior to ischemia attenuated ischemic brain damage in both mice tMCAO and pMCAO models and treatment with VPA immediately after reperfusion reduced the infarct area in the tMCAO model. VPA could therefore be evaluated for clinical use in stroke patients.

Identification of a brain specific protein that associates with a Refsum disease gene product, phytanoyl-CoA alpha-hydroxylase

Refsum disease is an autosomal recessive neurologic disorder of the lipid metabolism. Major diagnostic clinical findings include retinitis pigmentosa, peripheral polyneuropathy, cerebellar ataxia, increased cerebrospinal fluid protein without pleocytosis, nerve deafness, and cardiac involvement. We have identified a novel protein (PAHX-AP #1) associated with phytanoyl-CoA alpha-hydroxylase (PAHX), a Refsum disease gene product, using the yeast-based two-hybrid assay. The middle portion (amino acids 83-264) of PAHX was used as a bait and a mouse brain cDNA library was searched. The ability of PAHX-AP #1 to interact with PAHX was confirmed using immunoprecipitation and Western blot studies in NIH3T3 cells which stably expressed both PAHX and PAHX-AP #1. Northern and Western blot analyses demonstrated a unique pattern of developmental PAHX-AP #1 expression which was targeted to the adult brain, but ubiquitous expressions of PAHX were observed in all examined tissues. In situ hybridization analyses of the brain showed specific localization of PAHX-AP #1 to the supragranular layer in the cerebral cortex, dentate gyrus, hippocampus, Purkinje cell layer, deep cerebellar nucleus, trigeminal nucleus, abducent nucleus, facial nucleus, cochlear and vestibular nucleus, ganglion cell and nuclear layer of the retina. These data indicate that localization of PAHX-AP #1 in the brain is correlated with central neurologic symptoms of Refsum disease such as retinitis pigmentosa, cerebellar ataxia, nerve deafness and suggest that PAHX-AP #1 may be involved in the development of the central neurologic deficits of Refsum disease.

The promoter of brain‐specific angiogenesis inhibitor 1‐associated protein 4 drives developmentally targeted transgene expression mainly in adult cerebral cortex and hippocampus

Restricting transgene expression to specific cell types and maintaining long‐term expression are major goals for gene therapy. Previously, we cloned brain‐specific angiogenesis inhibitor 1‐associated protein 4 (BAI1‐AP4), a novel brain‐specific protein that interacts with BAI1, and found that it was developmentally upregulated in the adult brain. In this report, we isolated 5 kb of the 5′ upstream sequence of the mouse BAI1‐AP4 gene and analyzed its promoter activity. Functional analyses demonstrated that an Sp1 site was the enhancer, and the region containing the transcription initiation site and an AP2‐binding site was the basal promoter. We examined the ability of the BAI1‐AP4 promoter to drive adult brain‐specific expression by using it to drive lacZ expression in transgenic (TG) mice. Northern blot analyses showed a unique pattern of β‐galactosidase expression in TG brain, peaking at 1 month after birth, like endogenous BAI1‐AP4. Histological analyses demonstrated the same localization and developmental expression of β‐galactosidase and BAI1‐AP4 in most neurons of the cerebral cortex and hippocampus. Our data indicate that TG mice carrying the BAI1‐AP4 promoter could be a valuable model system for region‐specific brain diseases.

Introduction of Tyramide Signal Amplification (TSA) to Pre-embedding Nanogold-Silver Staining at the Electron Microscopic Level

The tyramide signal amplification (TSA) technique has been shown to detect scarce tissue antigens in light and electron microscopy. In this study we applied the TSA technique at the electron microscopic level to pre-embedding immunocytochemistry. This protocol was compared to the non-amplified protocol. With the TSA protocol, the labeling of GM130, a cis-Golgi matrix protein, was tested in a cell line and found to be highly sensitive and more enhanced than that with the simple protocol. Moreover, the gold particles were well localized to the cis-side of the Golgi apparatus in both the TSA and the simple protocol.

Distribution and three-dimensional appearance of the interstitial cells of Cajal in the rat stomach and duodenum

The relationship between the interstitial cells of Cajal (ICC) and enteric nerves or smooth muscles cells is not fully defined. Presently, distribution and appearance of ICC in the rat stomach and duodenum was studied by immunohistochemistry, electron microscopy, and three‐dimensional reconstruction. c‐kit expressing ICC were regularly observed in the Auerbachs myenteric plexus (AP) of the stomach and duodenum. ICC in stomach and duodenum muscle layers was dissimilarly distributed. c‐kit immunoreactive cells were sparsely distributed in the stomach circular muscle layer but were abundant in the duodenum deep muscular plexus (DMP). Electron microscopy revealed that stomach ICC‐AP were irregular ovals with few cytoplasmic processes, and possessed an electron‐dense cytoplasm, numerous mitochondria, intermediate filaments, and caveolae. Duodenum and stomach ICC‐AP were similar in appearance. Ultrastructure observations and three‐dimensional reconstructions revealed ICC‐AP processes wrapping the nerve fibers and projecting into the space between smooth muscle cells. While ICC‐AP was occasionally close to enteric nerves or smooth muscle cells, no connections were observed. ICC‐DMP in duodenum was elongated and adopted the same cell axis orientation as the circular muscle cells. Unlike ICC‐AP, ICC‐DMP formed gap junctions with smooth muscle cells and had close contact with nerves. These results indicate that ICC‐AP is regularly distributed in stomach and duodenum, while ICC‐DMP is exclusively located in the duodenum. ICC‐DMP, which possess gap junctions and closely contacts nerves, may participate in neuromuscular transmission. Microsc. Res. Tech. 2009.