Release of RASSF1C from the nucleus by Daxx degradation links DNA damage and SAPK/JNK activation

Stress-activated protein kinase/c-Jun N-terminal kinase (SAPK/JNK) responds to a variety of stress stimuli and controls cell fates such as cell cycle entrance, apoptosis and senescence. Stimuli such as ultraviolet irradiation and chemical reagents that damage genomic DNA induce the activation of the SAPK/JNK signaling pathway. However, it is unclear how the signal arising in the nucleus owing to DNA damage is transmitted to SAPK/JNK in the cytoplasm. Here, we report that the nuclear components Daxx and Ras-association domain family 1C (RASSF1C) link DNA damage to SAPK/JNK activation in HeLa cells. In response to DNA damage, Daxx localized in promyelocytic leukaemia-nuclear bodies (PML-NBs) undergoes ubiquitination and degradation. RASSF1C, a tumor suppressor and newly identified binding partner of Daxx, is constitutively anchored by Daxx in PML-NBs but is released from the nucleus when Daxx is degraded. This released RASSF1C translocates to cytoplasmic microtubules and participates in the activation of SAPK/JNK. Our data define a novel mechanism by which the Daxx-RASSF1C complex in PML-NBs couples nuclear DNA damage to the cytoplasmic SAPK/JNK signaling pathway.     

Src homology 2 domain of overexpressed Lyn kinase is responsible for the acceleration of granulocyte colony-stimulating factor-induced neutrophilic nuclear lobulation

We have previously shown that the overexpression of a Src family kinase, Lyn, and its kinase-negative form, LynKN, in a granulocyte progenitor cell line, GM-I62M, accelerates neutrophilic nuclear lobulation when the cells are cultured in the presence of granulocyte colony-stimulating factor. In this study, we investigated the role of the Src homology 2 (SH2) and SH3 domains of Lyn in the accelerated induction of nuclear lobulation. In contrast to wild-type Lyn, the overexpression of its SH2 domain mutant did not induce the accelerated nuclear morphological changes, but the overexpressed SH3 domain mutant had the same effects as wild-type Lyn. Therefore, the SH2 domain of Lyn is responsible for the accelerated induction of neutrophilic nuclear lobulation upon G-CSF stimulation.     

Adenosine A3 receptor is involved in ADP-induced microglial process extension and migration

The extension of microglial processes toward injured sites in the brain is triggered by the stimulation of the purinergic receptor P2Y(12) by extracellular ATP. We recently showed that P2Y(12) stimulation by ATP induces microglial process extension in collagen gels. In the present study, we found that a P2Y(12) agonist, 2-methylthio-ADP (2MeSADP), failed to induce the process extension of microglia in collagen gels and that co-stimulation with adenosine, a phosphohydrolytic derivative of ATP, and 2MeSADP restored the chemotactic process extension. An adenosine A3 receptor (A3R)-selective agonist restored the chemotactic process extension, but other receptor subtype agonists did not. The removal of adenosine by adenosine deaminase and the blocking of A3R by an A3R-selective antagonist inhibited ADP-induced process extension. The A3R antagonist inhibited ADP-induced microglial migration, and an A3R agonist promoted 2MeSADP-stimulated migration. ADP and the A3R agonist activated Jun N-terminal kinase in microglia, and a Jun N-terminal kinase inhibitor inhibited the ADP-induced process extension. An RT-PCR analysis showed that A1R and A3R were expressed by microglia sorted from adult rat brains and that the A2AR expression level was very low. These results suggested that A3R signaling may be involved in the ADP-induced process extension and migration of microglia.     

Flavonol glycosides with lipid accumulation inhibitory activity from Sedum sarmentosum

Three new flavonol glycosides, sarmenosides V–VII (1–3), were isolated from the whole plant of Sedum sarmentosum (Crassulaseae). The structures of 1–3 were determined on the basis of spectroscopic analysis. Among the flavonoid constituents from S. sarmentosum, 1 and 3 were found to show oleic acid–albumin-induced lipid accumulation inhibitory activity.     

Rapid induction of large chromosomal deletions by a Cre/inverted loxP system in mouse ES Cell hybrids

Loss of heterozygosity by whole or partial loss of chromosomal regions is crucial to genetic disorders, cancers and diseases. It is difficult to analyze the mechanisms of pathogenesis caused by large-scale chromosomal abnormalities due to the extreme rarity of this mutagenesis. Using a Cre/inverted loxP system, we have generated a chromosome elimination cassette (CEC) that induces a selective loss of embryonic-stem-cell-derived chromosomes in undifferentiated embryonic stem cell-somatic cell hybrids. Here, due to the increased expression of Cre, rapid formation of Cre recombination products and immediate loss of CEC-tagged chromosomes were detected by fluorescence in situ hybridization. Cre also initiated intrachromosomal recombination between identical short sequences outside loxP, leading to large chromosomal deletions of CEC-tagged regions. The Cre-mediated antiparallel synapses likely act as a scaffold to bring the identical short sequences into close proximity for recombination. This CEC technology might allow better understanding of the modulator sequences responsible for the tangled structure formation and its solution mechanism, inducing mitotic recombination leading to chromosomal deletions.     

MURC, a muscle-restricted coiled-coil protein that modulates the Rho/ROCK pathway, induces cardiac dysfunction and conduction disturbance

We identified a novel muscle-restricted putative coiled-coil protein, MURC, which is evolutionarily conserved from frog to human. MURC was localized to the cytoplasm with accumulation in the Z-line of the sarcomere in the murine adult heart. MURC mRNA expression in the heart increased during the developmental process from the embryonic stage to adulthood. In response to pressure overload, MURC mRNA expression increased in the hypertrophied heart. Using the yeast two-hybrid system, we identified the serum deprivation response (SDPR) protein, a phosphatidylserine-binding protein, as a MURC-binding protein. MURC induced activation of the RhoA/ROCK pathway, which modulated serum response factor-mediated atrial natriuretic peptide (ANP) expression and myofibrillar organization. SDPR augmented MURC-induced transactivation of the ANP promoter in cardiomyocytes, and RNA interference of SDPR attenuated the action of MURC on the ANP promoter. Transgenic mice expressing cardiac-specific MURC (Tg-MURC) exhibited cardiac contractile dysfunction and atrioventricular (AV) conduction disturbances with atrial chamber enlargement, reduced thickness of the ventricular wall, and interstitial fibrosis. Spontaneous episodes of atrial fibrillation and AV block were observed in Tg-MURC mice. These findings indicate that MURC modulates RhoA signaling and that MURC plays an important role in the development of cardiac dysfunction and conduction disturbance with increased vulnerability to atrial arrhythmias.     

Study of thermodynamic parameters for solubilization of plant sterol and stanol in bile salt micelles

We investigated the difference between the molecular structures of plant sterols and stanols that affect the solubilization of cholesterol in bile salt micelles (in vitro study). First, the aqueous solubility of beta-sitosterol, beta-sitostanol, and campesterol was determined by considering the specific radioactivity by using a fairly small quantity of each radiolabeled compound. The order of their aqueous solubilities was as follows: cholesterol > campesterol > beta-sitostanol > beta-sitosterol. The maximum solubility of cholesterol and the above mentioned sterol/stanol in sodium taurodeoxycholate and sodium taurocholate solutions (single solubilizate system) was measured. Moreover, the preferential solubilization of cholesterol in bile salt solutions was systematically studied by using different types of plant sterols/stanols. The solubilization results showed that the cholesterol-lowering effect was similar for sterols and stanol. Thermodynamic analysis was applied to these experimental results. The Gibbs energy change (Delta G degrees ) for the solubilization of plant sterols/stanols showed a negative value larger than that for cholesterol.     

Gene application with in utero electroporation in mouse embryonic brain

Mouse genetic manipulations, such as the production of gene knock-out, knock-in, and transgenic mice, have provided excellent systems for analysis of numerous genes functioning during development. Nevertheless, the lack of specific promoters and enhancers that control gene expression in specific regions and at specific times, limits usage of these techniques. However, progress in in utero systems of electroporation into mouse embryos has opened a new window, permitting new approaches to answering important questions. Simple injection of plasmid DNA solution and application of electrical current to mouse embryos results in transient area- and time-dependent transfection. Further modification of the technique, arising from variations in types of electrodes used, has made it possible to control the relative size of the region of transfection, which can vary from a few cells to entire tissues. Thus, this technique is a powerful means not only of characterizing gene function in various settings, but also of tracing the migratory routes of cells, due to its high efficiency and the localization of gene expression it yields. We summarize here some of the potential uses and advantages of this technique for developmental neuroscience research.     

Fgf8 controls regional identity in the developing thalamus

The vertebrate thalamus contains multiple sensory nuclei and serves as a relay station to receive sensory information and project to corresponding cortical areas. During development, the progenitor region of the diencephalon is divided into three parts, p1, p2 (presumptive thalamus) and p3, along its longitudinal axis. Besides the local expression of signaling molecules such as sonic hedgehog (Shh), Wnt proteins and Fgf8, the patterning mechanisms of the thalamic nuclei are largely unknown. Using mouse in utero electroporation to overexpress or inhibit endogenous Fgf8 at the diencephalic p2/p3 border, we revealed that it affected gene expression only in the p2 region without altering overall diencephalic size or the expression of other signaling molecules. We demonstrated that two distinctive populations in p2, which can be distinguished by Ngn2 and Mash1 in early embryonic diencephalon, are controlled by Fgf8 activity in complementary manner. Furthermore, we found that FGF activity shifts thalamic sensory nuclei on the A/P axis in postnatal brain. Moreover, gene expression analysis demonstrated that FGF signaling shifts prethalamic nuclei in complementary manner to the thalamic shift. These findings suggest conserved roles of FGF signaling in patterning along the A/P axis in CNS, and reveal mechanisms of nucleogenesis in the developing thalamus.