Brain-specific gene expression by immortalized microglial cell-mediated gene transfer in the mammalian brain

AbstractThe intra-arterial injection of immortalized microglia transfected with the lacZ gene, resulted in the expression of β-galactosidase in the rat brain at 48 h and the activity of β-galactosidase was detected for up to 3 weeks post-injection. More than 30-fold higher activity of β-galactosidase was detected in the brain than in the liver, lung or spleen at 48 h post-injection. This method allows us to easily deliver the gene of interest to the brain without influencing other organs. Our brain-targeting gene delivery system can facilitate gene therapy of several brain disorders, including brain tumor, metabolic disorders, and degenerative disorders, as well as investigation into the roles of particular genes in brain function and development

The Life and Science of Professor Tsuneko Okazaki, and her time at Fujita Health University

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Remembering Keisuke Fujita, M.D., Ph.D., President and Founder of Fujita Health University, and his contributions to medical science and education

Keisuke Fujita, M.D., Ph.D. (1925–1995), founded and was President of Fujita Gakuen (academy) in 1964, Fujita Health University in 1968, and Fujita Health University (FHU) School of Medicine in 1972. He also established the Institute for Comprehensive Medical Science (ICMS) at FHU in 1972, at the same time as the founding of FHU School of Medicine, to promote the institutional development of FHU School of Medicine by providing a strong foundation for science. I collaborated with Dr. Fujita from 1965. Returning from the study abroad at the NIH in the USA in 1965, I joined Professor Fujita’s Department of Biochemistry at the Aichi Gakuin University School of Dentistry, as an Associate Professor. Dr. Fujita’s major research interest was in the biochemistry of diseases, namely, cancer, neuropsychiatric diseases, and various intractable diseases, which he investigated by applying analytical chemistry and molecular/cellular biochemistry. He was also interested in the pharmacognosy of aloe plants and established “Syoyaku Kenkyu Juku (Center for Pharmacognosy),” and where he studied by himself and trained many FHU graduates. I herein present an overview of the research carried out by Dr. Fujita to share his legacy and praise his memoir and contributions to medical science and education for all faculty members, staffs and students of FHU. It is assumed that individuals at FHU have already made significant contributions to medical science. I hope that his vision of FHU producing a Nobel Prize laureate will be realized someday

A SENSITIVE ASSAY FOR NON-SPECIFIC N-METHYLTRANSFERASE ACTIVITY IN RAT TISSUES BY HIGH-PERFORMANCE LIQUID CHROMATOGRAPHY ELECTROCHEMICAL DETECTION

Phenylethanolamine N-methyltransferase (PNMT) and non-specific N -methyltransferase  (EC 2.1.1.28) catalyze the N-methylation of aromatic amines. PNMT is specific for phenylethanolamines such as noradrenaline (NA). and catalyzes the step in catecholamine biosynthesis, forming adrenaline (AD) from NA. PNMT activity is high in adrenal gland, whereas non-specific N-methyltransferase is distributed in various tissues such as the lungs. Borchardt et al. first reported a method to detect PNMT activity by  high-performance liquid chromatography electrochemical detection (HPLC-EICD), which could demonstrate the activity only in the adrenal medulla and hypothalamus. Recently, Troeewicz et al. reported a highly sensitive assay method for PNMT using HPLC-EICD by which the activity in all regions of rat brains could be measured. The activity of non-specific N-methyltransferase in brain regions and peripheral tissues of the rat could be detected by a radioassay. However, there has been no repot on an assay method for non-specific N-methyltransferase using HPLC-EICD. In this paper, we describe a highly sensitive assay procedure for the activity of non-specific N-methyltransferase by high-performance reversed-phase ion pair chromatography with electrochemical detection. By this method, the non-specific N-methyltransferase activity could be determined in various rat brain regions and peripheral tissues