Crystal structure of Cex1p reveals the mechanism of tRNA trafficking between nucleus and cytoplasm

In all eukaryotes, transcribed precursor tRNAs are maturated by processing and modification processes in nucleus and are transported to the cytoplasm. The cytoplasmic export protein (Cex1p) captures mature tRNAs from the nuclear export receptor (Los1p) on the cytoplasmic side of the nuclear pore complex, and it delivers them to eukaryotic elongation factor 1α. This conserved Cex1p function is essential for the quality control of mature tRNAs to ensure accurate translation. However, the structural basis of how Cex1p recognizes tRNAs and shuttles them to the translational apparatus remains unclear. Here, we solved the 2.2 Å resolution crystal structure of Saccharomyces cerevisiae Cex1p with C-terminal 197 disordered residues truncated. Cex1p adopts an elongated architecture, consisting of N-terminal kinase-like and a C-terminal α-helical HEAT repeat domains. Structure-based biochemical analyses suggested that Cex1p binds tRNAs on its inner side, using the positively charged HEAT repeat surface and the C-terminal disordered region. The N-terminal kinase-like domain acts as a scaffold to interact with the Ran-exportin (Los1p·Gsp1p) machinery. These results provide the structural basis of Los1p·Gsp1p·Cex1p·tRNA complex formation, thus clarifying the dynamic mechanism of tRNA shuttling from exportin to the translational apparatus.     

Development of a 16S rRNA gene primer and PCR-restriction fragment length polymorphism method for rapid detection of members of the genus Megasphaera and species-level identification

The genus Megasphaera is relevant to the environment, human health and food, and renewable energy for the future. In this study, a primer set was designed for PCR-restriction fragment length polymorphism (RFLP) analyses to detect and identify the members of Megasphaera. Direct detection and identification were achieved for environmental samples and isolates.     

G alpha(q) signal in osteoblasts is inhibitory to the osteoanabolic action of parathyroid hormone

This study examined the role of the Gα(q) signal constituted by Gα(q) and Gα(11) (encoded by Gnα(q) and Gnα(11), respectively), a major intracellular pathway of parathyroid hormone (PTH), in the PTH osteoanabolic action by the gain- and loss-of-function analyses. Transgenic mice with osteoblast-specific overexpression of the constitutively active Gnα(q) gene under the control of 2.3-kb type I collagen α1 chain (Col1a1) promoter exhibited osteopenia with decreased bone formation parameters and did not respond to the daily PTH treatment. We then established osteoblast-specific Gnα(q) and Gnα(11) double-knock-out (cDKO) mice by crossing the 2.3-kb Col1a1 promoter-Cre recombinase transgenic mice and those with Gnα(q) gene flanked with loxP and global ablation of Gnα(11) (Col1a1-Cre(+/-);Gna(q)(fl/fl);Gna(11)(-/-)) and found that the cDKO and single knock-out littermates of Gnα(q) or Gnα(11) exhibited normal bone volume and turnover under physiological conditions. With a daily injection of PTH, however, the cDKO mice, but not the single knock-out mice, showed higher bone volume and turnover than the wild-type littermates. Cultures of primary osteoblasts derived from cDKO and wild-type littermates confirmed enhancement of the PTH osteoanabolic action by the Gα(q) signal deficiency in a cell-autonomous mechanism, in association with the membrane translocation of protein kinase Cδ. This enhancement was reproduced by overexpression of regulator of G protein signaling-2, a Gα(q) signal inhibitor, in osteoblastic MC3T3-E1 cells. Hence, the Gα(q) signal plays an inhibitory role in the PTH osteoanabolic action, suggesting that its suppression may lead to a novel treatment in combination with PTH against osteoporosis.     

Regulation of Cellular Functions by Nucleoside Diphosphate Kinases in Mammals

The role of nucleoside diphosphate (NDP) kinases in cell growth, differentiation, and tumormetastasis in relation to signal transduction was investigated. The essential role of NDP kinasein cell growth was validated by coupling between reduced NDP kinase levels, induced byantisense oligonucleotides, and the suppression of proliferative activity of a cultured cell line.In addition, because NDP kinase levels are often enhanced with development and differentiation,as has been demonstrated in postmitotic cells and tissues, such as the heart and brain, wefurther examined this possibility using the bone tissue (osteoblasts) and a cultured cell linePC12D. The enhanced NDP kinase accumulation was demonstrated in the matured osteoblastsin vivo and in vitro by immunohistochemistry. In PC12D cells neurite outgrowth took placein NDP kinase -transfected clones without differentiation inducers, which was accompaniedby prolongation of doubling time. Neurite outgrowth, triggered by nerve growth factor and acyclic AMP analog, was down-regulated upon forced expression of inactive mutant NDPkinase by virtue of a dominant negative effect. NDP kinase -transfected rat mammaryadenocarcinoma cells (MTLn3) and nm23-H2-transfected human oral squamous cell carcinomacells (LMF4) manifested reduced metastatic potential and were associated with an alteredsensitivity to environmental factors, such as motility and growth factors. NDP kinase ,compared to NDP kinase , was involved in a wide variety of the cellular phenomena examined.Taken together, NDP kinase isoforms appear to elicit both their own respective and commoneffects. They may have an ability to lead cells to both proliferative and differentiated statesby modulating responsiveness to environmental factors, but their fate seems to depend on theirsurrounding milieu.