Identification of a polo-like kinase 4-dependent pathway for de novo centriole formation

Supernumerary centrosomes are a key cause of genomic instability in cancer cells. New centrioles can be generated by duplication with a mother centriole as a platform or, in the absence of preexisting centrioles, by formation de novo. Polo-like kinase 4 (Plk4) regulates both modes of centriole biogenesis, and Plk4 deregulation has been linked to tumor development. We show that Plx4, the Xenopus homolog of mammalian Plk4 and Drosophila Sak, induces de novo centriole formation in vivo in activated oocytes and in egg extracts, but not in immature or in vitro matured oocytes. Both kinase activity and the polo-box domain of Plx4 are required for de novo centriole biogenesis. Polarization microscopy in "cycling" egg extracts demonstrates that de novo centriole formation is independent of Cdk2 activity, a major difference compared to template-driven centrosome duplication that is linked to the nuclear cycle and requires cyclinA/E/Cdk2. Moreover, we show that the Mos-MAPK pathway blocks Plx4-dependent de novo centriole formation before fertilization, thereby ensuring paternal inheritance of the centrosome. The results define a new system for studying the biochemical and molecular basis of de novo centriole formation and centriole biogenesis in general.     

The habitat disruption induces immune-suppression and oxidative stress in honey bees

The honey bee is a major insect used for pollination of many commercial crops worldwide. Although the use of honey bees for pollination can disrupt the habitat, the effects on their physiology have never been determined. Recently, honey bee colonies have often collapsed when introduced in greenhouses for pollination in Japan. Thus, suppressing colony collapses and maintaining the number of worker bees in the colonies is essential for successful long-term pollination in greenhouses and recycling of honey bee colonies. To understand the physiological states of honey bees used for long-term pollination in greenhouses, we characterized their gene expression profiles by microarray. We found that the greenhouse environment changes the gene expression profiles and induces immune-suppression and oxidative stress in honey bees. In fact, the increase of the number of Nosema microsporidia and protein carbonyl content was observed in honey bees during pollination in greenhouses. Thus, honey bee colonies are likely to collapse during pollination in greenhouses when heavily infested with pathogens. Degradation of honey bee habitat by changing the outside environment of the colony, during pollination services for example, imposes negative impacts on honey bees. Thus, worldwide use of honey bees for crop pollination in general could be one of reasons for the decline of managed honey bee colonies.     

Investigation by imaging mass spectrometry of biomarker candidates for aging in the hair cortex

Background

Human hair is one of the essential components that define appearance and is a useful source of samples for non-invasive biomonitoring. We describe a novel application of imaging mass spectrometry (IMS) of hair biomolecules for advanced molecular characterization and a better understanding of hair aging. As a cosmetic and biomedical application, molecules whose levels in hair altered with aging were comprehensively investigated.

Methods

Human hair was collected from 15 young (20±5 years old) and 15 older (50±5 years old) volunteers. Matrix-free laser desorption/ionization IMS was used to visualize molecular distribution in the hair sections. Hair-specific ions displaying a significant difference in the intensities between the 2 age groups were extracted as candidate markers for aging. Tissue localization of the molecules and alterations in their levels in the cortex and medulla in the young and old groups were determined.

Results

Among the 31 molecules detected specifically in hair sections, 2—one at m/z 153.00, tentatively assigned to be dihydrouracil, and the other at m/z 207.04, identified to be 3,4-dihydroxymandelic acid (DHMA)—exhibited a higher signal intensity in the young group than in the old, and 1 molecule at m/z 164.00, presumed to be O-phosphoethanolamine, displayed a higher intensity in the old group. Among the 3, putative O-phosphoethanolamine showed a cortex-specific distribution. The 3 molecules in cortex presented the same pattern of alteration in signal intensity with aging, whereas those in medulla did not exhibit significant alteration.

Conclusion

Three molecules whose levels in hair altered with age were extracted. While they are all possible markers for aging, putative dihydrouracil and DHMA, are also suspected to play a role in maintaining hair properties and could be targets for cosmetic supplementation. Mapping of ion localization in hair by IMS is a powerful method to extract biomolecules in specified regions and determine their tissue distribution.     

Loosening Xyloglucan Accelerates the Enzymatic Degradation of Cellulose in Wood

In order to create trees in which cellulose, the most abundant component in biomass, can be enzymatically hydrolyzed highly for the production of bioethanol, we examined the saccharification of xylem from several transgenic poplars, each overexpressing either xyloglucanase, cellulase, xylanase, or galactanase. The level of cellulose degradation achieved by a cellulase preparation was markedly greater in the xylem overexpressing xyloglucanase and much greater in the xylems overexpressing xylanase and cellulase than in the xylem of the wild-type plant. Although a high degree of degradation occurred in all xylems at all loci, the crystalline region of the cellulose microfibrUs was highly degraded in the xylem overexpressing xyloglucanase. Since the complex between microfibrils and xyloglucans could be one region that is particularly resistant to cellulose degradation, loosening xyloglucan could facilitate the enzymatic hydrolysis of cellulose in wood.     

Structure of the carboxypeptidase Y inhibitor IC in complex with the cognate proteinase reveals a novel mode of the proteinase-protein inhibitor interaction

Carboxypeptidase Y (CPY) inhibitor, IC, shows no homology to any other known proteinase inhibitors and rather belongs to the phosphatidylethanolamine-binding protein (PEBP) family. We report here on the crystal structure of the IC-CPY complex at 2.7 A resolution. The structure of IC in the complex with CPY consists of one major beta-type domain and a N-terminal helical segment. The structure of the complex contains two binding sites of IC toward CPY, the N-terminal inhibitory reactive site (the primary CPY-binding site) and the secondary CPY-binding site, which interact with the S1 substrate-binding site of CPY and the hydrophobic surface flanked by the active site of the enzyme, respectively. It was also revealed that IC had the ligand-binding site, which is conserved among PEBPs and the putative binding site of the polar head group of phospholipid. The complex structure and analyses of IC mutants for inhibitory activity and the binding to CPY demonstrate that the N-terminal inhibitory reactive site is essential both for inhibitory function and the complex formation with CPY and that the binding of IC to CPY constitutes a novel mode of the proteinase-protein inhibitor interaction. The unique binding mode of IC toward the cognate proteinase provides insights into the inhibitory mechanism of PEBPs toward serine proteinases and into the specific biological functions of IC belonging to the PEBP family as well.     

Production of soluble matriptase by human cancer cell lines and cell surface activation of its zymogen by trypsin

The membrane-bound serine proteinase matriptase, which is often released from the plasma membrane of epithelial and carcinoma cells, has been implicated to play important roles in both physiological and pathological conditions. However, the regulatory mechanism of its activity is poorly understood. In the present study, we examined expression and activation state of soluble matriptase in 24 human cancer cell lines. Soluble matriptase was detected in the conditioned media from all of 5 colon and 4 breast carcinoma cell lines and 8 of 10 stomach carcinoma cell lines tested. Only two of five lung cancer cell lines released the matriptase protein into the culture media. Out of the five matriptase-negative cell lines, two cell lines expressed the matriptase mRNA. Among 24 cancer cell lines tested, 13 cell lines secreted trypsin in an active or latent form and all of them released matriptase. Most of the 24 cell lines released a latent, single-chain matriptase of 75 kDa as a major form, as well as low levels of complex forms of an activated two-chain enzyme with its specific inhibitor HAI-1. Thus, these soluble matriptases appeared to have little proteolytic activity. Treatment of stomach and colon cancer cell lines with epidermal growth factor stimulated the release of matripatase/HAI-1 complexes. In cancer cell lines secreting active trypsin, however, matriptase was released mostly as an inhibitor-free, two-chain active form. Trypsin seemed to activate the membrane-bound, latent matriptase on the cell surface. These results suggest that matriptase and trypsin cooperatively function for extracellular proteolysis.     

Rapid Ca2+-dependent increase in oxygen consumption by mitochondria in single mammalian central neurons

Oxygen consumption increases within a fraction of a second after the onset of neuronal activity, a phenomenon referred to as the "initial dip" in functional imaging studies of the living brain. The cellular mechanism that underlies this rapid increase in oxygen consumption has remained unclear, however. We have now used two-photon excitation imaging to characterize rapid activity-dependent mitochondrial responses in single neurons. This approach allowed simultaneous multicolor imaging of individual mitochondria in single mouse Purkinje neurons in culture. Mitochondrial depolarization was induced immediately when the cytosolic free Ca(2+) concentration ([Ca(2+)](i)) exceeded 15 microM and was associated with oxidation of mitochondrial NAD(P)H, suggesting that Ca(2+)-induced mitochondrial depolarization mediated by the Ca(2+) uniporter directly facilitated oxidation of NAD(P)H. With the use of a miniature oxygen electrode, we detected a burst of oxygen consumption within 0.2s after the onset of cell depolarization in single Purkinje neurons, and this rapid increase in oxygen consumption was dependent on the increase in [Ca(2+)](i). We have thus demonstrated a rapid Ca(2+)-dependent consumption of oxygen that is mediated by mitochondrial depolarization in mammalian central neurons. This process might function as a rapid feed-forward mechanism in homeostatic control of the cytosolic ATP concentration.     

Long-term treatment with the Na+-glucose cotransporter inhibitor T-1095 causes sustained improvement in hyperglycemia and prevents diabetic neuropathy in Goto-Kakizaki Rats

We examined the effects of T-1095, an orally active inhibitor of Na(+)-glucose cotransporter (SGLT), on the development and severity of diabetes in Goto-Kakizaki (GK) rat, a spontaneous, non-obese model of type 2 diabetes. T-1095 was administered as dietary admixture (0.1% w/w) beginning at 7 weeks of age for 32 weeks. Untreated male GK rats were hyperglycemic compared with Wistar rats. Throughout the study, T-1095 treatment significantly decreased both blood glucose and hemoglobin A(1C) levels in the GK rats. The concomitant increase of urinary glucose excretion indicated that the hypoglycemic action of T-1095 is derived from the enhancement of urinary glucose disposal. Although food intake was not changed in the T-1095-treated rats, the body weight gain was retarded. T-1095 treatment partially ameliorated oral glucose tolerance but not the impaired glucose-induced insulin secretion. Homeostasis model assessment (HOMA) indicated the existence of insulin resistance in GK rats and a significant restoration by T-1095-treatment. There was a reduction of the thermal response in tail-flick testing following long-term hyperglycemia (diabetic neuropathy). Treatment of T-1095 significantly prevented the development of diabetic neuropathy in male GK rats. Sustained improvement of hyperglycemia and prevention of diabetic neuropathy by the T-1095-treatment provide further support the use of SGLT inhibitors for the treatment of diabetes.     

Cell differentiation inducers derived from thalidomide

5-Hydroxy- and 4-amino-2-(2,6-diisopropylphenyl)-1H-isoindole-1,3-dione (5HPP-33 and 4APP-33, respectively) have been shown to possess cell differentiation-inducing activity toward human leukemia cell line HL-60.