Environmental DNA monitoring method of the commercially important and endangered fish Gnathopogon caerulescens

Limnology - Gnathopogon caerulescens is an endangered but commercially important fish in Lake Biwa, Japan. The population size of G. caerulescens has drastically reduced in the past decades, and...     

Embryonic stem cell differentiation system for evaluating gene functions involved in physiological megakaryocytic differentiation

Megakaryocytic differentiation is accompanied by marked morphological changes induced by endomitosis and proplatelet formation. Molecular mechanisms underlying this unique cell differentiation process have been investigated by gain/loss-of-function studies using leukemic cell lines. However, these cell lines cannot completely mimic physiological megakaryocytic differentiation, including the morphological changes, and sometimes lead to contradictory results between cell lines. The goal of this study was to establish a novel cell differentiation system that completely mimics physiological megakaryocytic differentiation for analyzing gene function. To that end, we used homologous recombination to prepare an embryonic stem (ES) cell line containing a GFP-transgene driven by the PF4 promoter at the Hprt locus. Differentiation of these cells resulted in megakaryocytes and proplatelets, suggesting physiological megakaryocytic differentiation. However, the number of GFP-expressing cells was low (1.7% GFP(+) cells among CD41(+) cells). Insertion of full-length or small core β-globin insulators on either side of the transgene significantly increased the number of GFP-expressing cells (～60% GFP(+) cells among CD41(+) cells), and GFP-expression was specifically observed in megakaryocytic cells. Similar results were obtained with other ES cells containing a GPIIb-GFP transgene. Altogether, we have succeeded in efficiently expressing exogenous genes specifically in differentiating megakaryocytes and in establishing a novel ES cell differentiation system for analyzing gene function involved in physiological megakaryocytic differentiation.     

Metabolism of Cyanox®, O,O-Dimethyl O-(4-Cyanophenyl) Phosphorothioate in the Rats

Orally administered Cyanox, O, O-dimethyl O-(4-cyanophenyl) phosphorothioate, labelled with carbon-14 at p-cyano group was easily absorbed from the gastrointestinal tract of male Wistar rats, and distributed into tissues. Elimination of the radioactivity was rapid and essentially complete; namely during 96 hr approximately 90.7% and 10% of total radioactivity were excreted respectively into urine and feces. Carbon-14 in expiration was negligible. No detectable amount of Cyanox was found in the urine and 0.01% of the administered compound was present in the feces. Degradation products in the urine were identified as demethylcyanox, demethylcyanoxon, p-cyanophenol and p-cyanophenylsulfate.     

Multiple ETS family proteins regulate PF4 gene expression by binding to the same ETS binding site

In previous studies on the mechanism underlying megakaryocyte-specific gene expression, several ETS motifs were found in each megakaryocyte-specific gene promoter. Although these studies suggested that several ETS family proteins regulate megakaryocyte-specific gene expression, only a few ETS family proteins have been identified. Platelet factor 4 (PF4) is a megakaryocyte-specific gene and its promoter includes multiple ETS motifs. We had previously shown that ETS-1 binds to an ETS motif in the PF4 promoter. However, the functions of the other ETS motifs are still unclear. The goal of this study was to investigate a novel functional ETS motif in the PF4 promoter and identify proteins binding to the motif. In electrophoretic mobility shift assays and a chromatin immunoprecipitation assay, FLI-1, ELF-1, and GABP bound to the -51 ETS site. Expression of FLI-1, ELF-1, and GABP activated the PF4 promoter in HepG2 cells. Mutation of a -51 ETS site attenuated FLI-1-, ELF-1-, and GABP-mediated transactivation of the promoter. siRNA analysis demonstrated that FLI-1, ELF-1, and GABP regulate PF4 gene expression in HEL cells. Among these three proteins, only FLI-1 synergistically activated the promoter with GATA-1. In addition, only FLI-1 expression was increased during megakaryocytic differentiation. Finally, the importance of the -51 ETS site for the activation of the PF4 promoter during physiological megakaryocytic differentiation was confirmed by a novel reporter gene assay using in vitro ES cell differentiation system. Together, these data suggest that FLI-1, ELF-1, and GABP regulate PF4 gene expression through the -51 ETS site in megakaryocytes and implicate the differentiation stage-specific regulation of PF4 gene expression by multiple ETS factors.