Osamu Urayama

The up-regulation of microRNA-335 is associated with lipid metabolism in liver and white adipose tissue of genetically obese mice.

MicroRNAs (miRNAs) are short non-coding RNA that post-transcriptionally regulates gene expression. Some miRNAs have been proposed to be associated with obesity. However, miRNAs, which are related to the development of obesity in vivo remains unknown. Here in, we found the up-regulation of miR-335 in obesity using microarray analysis for miRNA. The expressions of miR-335 in liver and white adipose tissue (WAT) were up-regulated in obese mice including ob/ob, db/db, and KKAy mice. Increased miR-335 expressions were associated with an elevated body, liver and WAT weight, and hepatic triglyceride and cholesterol. Furthermore, miR-335 levels were closely correlated with expression levels of adipocyte differentiation markers such as PPARgamma, aP2, and FAS in 3T3-L1 adipocyte. These findings provide the first evidence that the up-regulated expressions of miR-335 in liver and WAT of obese mice might contribute to the pathophysiology of obesity.

Laughter regulates gene expression in patients with type 2 diabetes

Background: Positive emotions influence endocrinological and immunological response. This study examined the effect of laughter,as an expression of positive emotion, in terms of gene expression changes. Methods: Using a microarray technique, we analyzed the changes in expression of 18,716 genes from peripheral blood leukocytes in patients with type 2 diabetes, which were induced by laughter. Results: Of the 18,716 genes, 23 genes showed significantly different expression changes after listening to the comic story compared to the lecture. Eight were relatively upregulated and 15 were downregulated 1.5 h after the laughing episode. However, these genes did not include genes that are directly involved in blood glucose metabolism. Among the 23 genes discriminated, all 4 genes encoding proteins involved in the immune response and all 4 signal transduction genes were downregulated. Moreover, it is noteworthy that 5 of the 8 relatively upregulated genes were related to the cell cycle, apoptosis, and cell adhesion. Conclusions: We demonstrated that laughter, which is an expression of positive emotion, is linked to gene expression. However, the finding of this study does not allow reasonable interpretation for the regulation of gene expression by laughter. A more focused study is needed that may identify the candidate genes for the association between physical condition and positive emotion.

TFE3 Controls Lipid Metabolism in Adipose Tissue of Male Mice by Suppressing Lipolysis and Thermogenesis

Transcription factor E3 (TFE3) is a transcription factor that binds to E-box motifs and promotes energy metabolism-related genes. We previously reported that TFE3 directly binds to the insulin receptor substrate-2 promoter in the liver, resulting in increased insulin response. However, the role of TFE3 in other tissues remains unclear. In this study, we generated adipose-specific TFE3 transgenic (aP2-TFE3 Tg) mice. These mice had a higher weight of white adipose tissue (WAT) and brown adipose tissue than wild-type (WT) mice under fasting conditions. Lipase activity in the WAT in these mice was lower than that in the WT mice. The mRNA level of adipose triglyceride lipase (ATGL), the rate-limiting enzyme for adipocyte lipolysis, was significantly decreased in aP2-TFE3 Tg mice. The expression of Foxo1, which directly activates ATGL expression, was also suppressed in transgenic mice. Promoter analysis confirmed that TFE3 suppressed promoter activities of the ATGL gene. In contrast, G0S2 and Perilipin1, which attenuate ATGL activity, were higher in transgenic mice than in WT mice. These results indicated that the decrease in lipase activity in adipose tissues was due to a decrease in ATGL expression and suppression of ATGL activity. We also showed that thermogenesis was suppressed in aP2-TFE3 Tg mice. The decrease in lipolysis in WAT of aP2-TFE3 Tg mice inhibited the supply of fatty acids to brown adipose tissue, resulting in the inhibition of the expression of thermogenesis-related genes such as UCP1. Our data provide new evidence that TFE3 regulates lipid metabolism by controlling the gene expression related to lipolysis and thermogenesis in adipose tissue.

Hepatic CREB3L3 Controls Whole-Body Energy Homeostasis and Improves Obesity and Diabetes

Transcriptional regulation of metabolic genes in the liver is the key to maintaining systemic energy homeostasis during starvation. The membrane-bound transcription factor cAMP-responsive element-binding protein 3-like 3 (CREB3L3) has been reported to be activated during fasting and to regulate triglyceride metabolism. Here, we show that CREB3L3 confers a wide spectrum of metabolic responses to starvation in vivo. Adenoviral and transgenic overexpression of nuclear CREB3L3 induced systemic lipolysis, hepatic ketogenesis, and insulin sensitivity with increased energy expenditure, leading to marked reduction in body weight, plasma lipid levels, and glucose levels. CREB3L3 overexpression activated gene expression levels and plasma levels of antidiabetic hormones, including fibroblast growth factor 21 and IGF-binding protein 2. Amelioration of diabetes by hepatic activation of CREB3L3 was also observed in several types of diabetic obese mice. Nuclear CREB3L3 mutually activates the peroxisome proliferator-activated receptor (PPAR) α promoter in an autoloop fashion and is crucial for the ligand transactivation of PPARα by interacting with its transcriptional regulator, peroxisome proliferator-activated receptor gamma coactivator-1α. CREB3L3 directly and indirectly controls fibroblast growth factor 21 expression and its plasma level, which contributes at least partially to the catabolic effects of CREB3L3 on systemic energy homeostasis in the entire body. Therefore, CREB3L3 is a therapeutic target for obesity and diabetes.

Dicer has a crucial role in the early stage of adipocyte differentiation, but not in lipid synthesis, in 3T3-L1 cells

Dicer is a rate-limiting enzyme for microRNA (miRNA) synthesis. To determine the effects of Dicer on adipogenesis, we performed stage-specific knockdown of Dicer using adenovirus encoding short-hairpin RNAi against Dicer in 3T3-L1 cells. When cells were infected with the adenovirus before induction of adipocyte differentiation, Dicer RNAi suppressed the gene expression of inducers of adipocyte differentiation such as PPARγ, C/EBPα, and FAS in 3T3-L1 cells during adipocyte differentiation. Concurrently, both adipocyte differentiation and cellular lipid accumulation were cancelled by Dicer RNAi when compared with control RNAi. Meanwhile, we addressed the roles of Dicer in lipid synthesis and accumulation in the final stages of differentiation. When the differentiated cells at day 4 after induction of differentiation were infected with adenovirus Dicer RNAi, cellular lipid accumulation was unchanged. Consistent with this, Dicer RNAi had no effects on the expression of genes related to cellular lipid accumulation, including PPARγ and FAS. Thus, Dicer controls proadipogenic genes such as C/EBPα and PPARγ in the early, but not in the late, stage of adipogenesis via regulation of miRNA synthesis.

Tickling stimulation causes the up-regulation of the kallikrein family in the submandibular gland of the rat

We recently showed that tactile stimulation (tickling) accompanied by positive emotion altered the expression of many genes in the rat hypothalamus (Hori et al., 2009 [15]). In this study, the effect of repeated tickling on gene expressions of the rat salivary gland was examined. After 4-week stimulation, several genes of the kallikrein (Klk) family were remarkably up-regulated and the alpha-amylase (amylase) gene was down-regulated in DNA microarray analysis. In quantitative analysis using real-time PCR of the submandibular gland of the rats tickled for 2 weeks, mRNAs of Klk1, Klk2 (Klk1c2, Tonin), Klk7 (Klk1l), Klk1b3 (Nerve growth factor, gamma), Klk1c10, Klks3 (Klk1c9) and GK11 were significantly 2-5-fold increased among 18 members of the Klk gene family examined and the submandibular amylase was decreased compared with the lightly touched and untouched control rats. In immunoblot analysis the increase in Klk7 protein was observed in the whole cell lysate fraction of the submandibular gland. In immunohistochemical analysis with anti-Klk7 polyclonal antibody, the immunostain was increased in duct cells of the submandibular gland of the tickled rat when compared with the lightly touched and untouched control rats. These results suggest that tactile sensory processing in the central nervous system affects the gene expression in the peripheral tissue probably via hormonal and/or autonomic neural activities. Submandibular Klks may be biochemical markers indicating positive emotional states.

Interprofessional Education Program of the University of Tsukuba: A Program to Develop Interprofessional Competence

This experience-based educational program is designed to train health professionals to provide a high level of interprofessional care. The program emphasizes practical learning and students’ experience in more than 10 health care professions in clinical settings. Introduced in 2004, the program has been administered jointly by three schools (Medicine, Nursing, and Medical Sciences) of the University of Tsukuba. The program features simulated care conferences and discussions in small groups consisting of students from the three schools. The program also provides opportunities for students to learn the viewpoints of patients and a variety of health professionals as well as the cooperative skills and partnerships required for interprofessional work. The program encourages students to understand the importance of cooperation among health professionals, to understand their expertise, and to learn how to develop the relationships necessary for providing interprofessional care.