Mutual Effects of Orexin and Bone Morphogenetic Proteins on Gonadotropin Expression by Mouse Gonadotrope Cells

Orexin plays a key role in the regulation of sleep and wakefulness and in feeding behavior in the central nervous system, but its receptors are expressed in various peripheral tissues including endocrine tissues. In the present study, we elucidated the effects of orexin on pituitary gonadotropin regulation by focusing on the functional involvement of bone morphogenetic proteins (BMPs) and clock genes using mouse gonadotrope L beta T2 cells that express orexin type 1 (OX1R) and type 2 (OX2R) receptors. Treatments with orexin A enhanced LH beta and FSH beta mRNA expression in a dose-dependent manner in the absence of GnRH, whereas orexin A in turn suppressed GnRH-induced gonadotropin expression in L beta T2 cells. Orexin A downregulated GnRH receptor expression, while GnRH enhanced OX1R and OX2R mRNA expression. Treatments with orexin A as well as GnRH increased the mRNA levels of Bmal1 and Clock, which are oscillational regulators for gonadotropin expression. Of note, treatments with BMP-6 and -15 enhanced OX1R and OX2R mRNA expression with upregulation of clock gene expression. On the other hand, orexin A enhanced BMP receptor signaling of Smad1/5/9 phosphorylation through upregulation of ALK-2/BMPRII among the BMP receptors expressed in L beta T2 cells. Collectively, the results indicate that orexin regulates gonadotropin expression via clock gene expression by mutually interacting with GnRH action and the pituitary BMP system in gonadotrope cells

Saposin B Is a Human Coenzyme Q10-Binding/Transfer Protein

Coenzyme Q10 (CoQ10) is essential for ATP production in the mitochondria, and is an important antioxidant in every biomembrane and lipoprotein. Due to its hydrophobicity, a binding and transfer protein for CoQ10 is plausible, but none have yet been isolated and characterized. Here we purified a CoQ10-binding protein from human urine and identified it to be saposin B, a housekeeping protein necessary for sphingolipid hydrolysis in lysosomes. We confirmed that cellular saposin B binds CoQ10 in human sperm and the hepatoma cell line HepG2 by using saposin B monoclonal antibody. The molar ratios of CoQ10 to saposin B were estimated to be 0.22 in urine, 0.003 in HepG2, and 0.12 in sperm. We then confirmed that aqueous saposin B extracts CoQ10 from hexane to form a saposin B-CoQ10 complex. Lipid binding affinity to saposin B decreased in the following order: CoQ10>CoQ9>CoQ7>>α-tocopherol>>cholesterol (no binding). The CoQ10-binding affinity to saposin B increased with pH, with maximal binding seen at pH 7.4. On the other hand, the CoQ10-donating activity of the saposin B-CoQ10 complex to erythrocyte ghost membranes increased with decreasing pH. These results suggest that saposin B binds and transports CoQ10 in human cells

Germline mutation of HRPT2 in patients with HPT

Background A subset of familial isolated primary hyperparathyroidism (FIHP) is a variant of hyperparathyroidism-jaw tumor syndrome (HPT-JT). Aim/Patients and Methods We investigated the involvement of the HRPT2, MEN1, and CASR genes in provisional 11 FIHP families and 2 HPT-JT families. Results Germline mutations of HRPT2 were found in 2 of 11 FIHP families and 1 of 2 HPT-JT families. One FIHP family with parathyroid carcinoma and atypical adenomas, and another FIHP family with cystic parathyroid adenoma had novel frameshift mutations of 518-521del and 62-66del, respectively. In a patient with HPT-JT, a de novo germline mutation of 39delC was detected. Novel somatic HRPT2 mutations of 70-73del and 95-102del were found in 2 of 5 parathyroid tumors in a family with 518-521del mutation. Biallelic inactivation of HRPT2 by a combination of germline mutation and somatic mutation was confirmed in parathyroid tumors. The finding that 2 families diagnosed with FIHP carried HRPT2 mutations suggests that they have occult HPT-JT. In the remaining 10 families, one family had a missense MEN1 mutation. No mutations of CASR were detected. Conclusion Our results confirm the need to test for HRPT2 in FIHP families, especially in those with parathyroid carcinomas, atypical adenomas, or adenomas with cystic change

ショウニトクハツセイネフローゼショウコウグンノチョウキツイセキケンキュウ : チョウキヨゴトジンソシキショケントノカンレン

京都大学0048新制・論文博士医学博士乙第3880号論医博第796号新制||医||262(附属図書館)6121UT51-54-H180(主査)教授 濱島 義博, 教授 太藤 重夫, 教授 奥田 六郎学位規則第5条第2項該当Kyoto UniversityDA

Trauma‐associated left renal vein thrombosis with nutcracker syndrome

Background Nutcracker syndrome is a compression of the left renal vein between the superior mesenteric artery and aorta, resulting in thrombogenesis. While renal vein thrombosis caused by renal disease is more common, solitary left renal vein thrombosis with nutcracker syndrome is rare. Case Presentation We present the case of a patient with trauma‐associated left renal vein thrombosis with nutcracker syndrome. A 24‐year‐old woman with low body mass index taking oral contraceptives was admitted for trauma. She had multiple injuries, including thoracolumbar fractures, for which elective spinal fusion surgery was scheduled. As the D‐dimer level elevated to 82.5 μg/dL preoperatively, enhanced computed tomography was performed, which revealed a solitary left renal vein thrombus. Conclusion This is the report of solitary left renal vein thrombosis in a patient with nutcracker syndrome after trauma. Patients with low body mass index and coagulopathy might have solitary left renal vein thrombosis associated with nutcracker syndrome

Development of a Fluorescence in Situ Hybridization Probe for Detecting IKZF1 Deletion Mutations in Patients with Acute Lymphoblastic Leukemia

Intragenic deletion of IKZF1 is a recurrent genomic alteration in acute lymphoblastic leukemia. The deletions are mediated by illegitimate variable(diversity)joining recombination via cryptic recombination signal sequences (RSSs). We developed a fluorescence in situ hybridization (FISH) probe set that can detect any type of IKZF1 deletion, including the commonly deleted exon 4 to 7 region. The probe set consists of a designed probe for the commonly deleted region (Cy3; red) and a bacterial artificial chromosomes clone probe for detecting the 3' flanking region (Spectrum Green). Intact IKZF1 showed a fusion signal, and the deleted allele showed loss of the red signal (0R1G1F). The FISH probes worked correctly for human leukemic cell lines and clinical samples. One case showed an atypical break-apart signal (1R1G1F). Inverse PCR of the case revealed rearrangement of the excised IKZF1 fragment into a legitimate RSS site at Ig κ on chromosome 2, suggesting a pathogenic role of this recombination-activating gene 1/2-mediated event. In this study, we established FISH probe detecting IKZF1 deletion in a quick, quantitative, and cost-effective manner, and the results provided a novel insight into B-cell receptor editing by rearrangement of a cryptic RSS-mediated genomic fragment in acute lymphoblastic leukemia pathology