French consumers’ marginal willingness to pay for the pairing of Japan’s fall chum salmon and rice wine (sake)

The pairing of foods and beverages (especially alcoholic beverages) is an effective marketing approach to promote the value of Japanese gastronomy to overseas consumers because it requires little additional cost. In this study, the research target was French consumers, and the evaluation targets were grilled fall-season wild chum salmon from Japan (mainly from Hokkaido) and Japanese rice wine (sake). The difference in the consumers’ willingness to pay (WTP) was evaluated using the contingent valuation method. In addition, we analyzed the determinants by applying Tobit regression. Our results revealed that there was a higher WTP when Japan’s (Hokkaido’s) grilled fall salmon and sake were presented as a set than when they were presented individually. The geographical identity of the origin of food and beverages can engender a positive premium to consumers through the synergistic effect of the origin of the brand.

     

Effects of Riparian Denitrification on Stream Nitrate-Evidence from Isotope Analysis and Extreme Nitrate Leaching during Rainfall-

The effects of riparian denitrification on stream nitrate were investigated by detailed soil water observations and isotope analysis at a small headwater catchment in an urban area near Tokyo, central Japan. In the base flow period, stream nitrate concentration (<100 µM) was comparable with that of riparian ground water which had less nitrate than unsaturated soil water. Nitrogen isotope analysis showed that the consumption of nitrate by denitrification took place in riparian ground water, suggesting that denitrification is an important process to control nitrate leaching to streams. During rainfall, the concentration of stream nitrate increased up to 400 µM, which was comparable with that of pre-event soil water. The fact that soil water nitrate directly leached to streams indicated that the riparian denitrification process did not work during rainfall because of the rapid discharge of water. A decrease of denitrification effects is a possible reason for high stream nitrate concentration during rainfall.     

Inhibition of diphenolase activity of tyrosinase by vitamin b(6) compounds

The vitamin B(6) compounds pyridoxine (PN), pyridoxamine (PM), pyridoxal (PL), and pyridoxamine 5'-phosphate (PMP) inhibited the diphenolase activity of mushroom tyrosinase. PM showed the highest inhibition; the control activity was inhibited by 38% at 1.5 mM. Each PL, PN, and PMP showed about 30% inhibition at the same concentration. Lineweaver-Burk plots showed that PM and PN were mixed-type inhibitors with K(I) values of 4.3 and 5.2 mM, respectively. Because PM and PN cannot form a Schiff base with a primary amino group of the enzyme, their inhibition is not attributable to the formation of the Schiff base. Alternatively, their quenching function of reactive oxygen species (ROS) was postulated to be responsible for the inhibition. Thus, the inhibitory effect of ROS was examined. The representative singlet oxygen quenchers l-histidine, sodium azide, Trolox, and anthracene-9,10-dipropionic acid (AAP) inhibited the activity. The specific scavenger of superoxide, proxyl fluorescamine, also inhibited the activity. The scavengers of hydroxyl radical, d-mannitol and dimethyl sulfoxide, showed no inhibition. The fluorescence of AAP was decayed during the diphenolase reaction, and PM inhibited the decay. AAP was also a mixed-type inhibitor. The results showed that the vitamin B(6) compounds inhibited the diphenolase activity by quenching ROS (probably singlet oxygen) generated during some reaction step of the diphenolase reaction.     

Transformation in Garnet from Orthorhombic Perovskite to LiNbO3 Phase on Release of Pressure

High-pressure in situ x-ray diffraction and transmission electron microscopy on quenched samples show that natural garnet transforms to orthorhombic perovskite (and minor coexisting phases) containing increasing amounts of aluminum with increasing pressure. This suggests that the perovskite is the dominant host mineral for aluminum in Earth's lower mantle. Orthorhombic perovskite is quenched from approximately 35 gigapascals but, because of the increased aluminum content, transforms to the LiNbO3 structure upon quenching from approximately 60 gigapascals.     

Lime-nitrogen application affects nitrification, denitrification, and N2O emission in an acidic tea soil

Lime-N (calcium cyanamide, CaCN₂) acts as both fertilizer and pesticide. Lime-N may reduce nitrous oxide (N₂O) emission from soil, although its effectiveness and the relative mechanisms are not well understood. The aim of the study was to quantify the effect of lime-N on N₂O emission from the acidic soil of tea fields. The study design consisted of two treatments: conventional fertilizer (CF) (application of conventional organo-chemical fertilizer) and lime-N (LN) (application of approximately 53 % of the applied N as lime-N and the remaining as conventional organo-chemical fertilizer). Both treatments had the same amount of N, P₂O₅, and K₂O applied to soil between plant canopies; fertilizer was incorporated into soil. We measured N₂O emissions and environmental and microbial parameters of soil between plant canopies and under the canopy of tea plants, including the concentrations of dicyandiamide and cyanamide derived from lime-N. Nitrous oxide emission from soil between plant canopies was lower in the LN treatment than in the CF treatment, and soil ammonium oxidation activity and soil denitrification rate decreased after lime-N application. We applied the acetylene inhibition technique and analyzed isotopomer ratios of N₂O; the results of both techniques suggested that denitrification was the major process of N₂O production in the soil between plant canopies, despite relatively low water-filled pore space. Cumulative N₂O emission over the 366 days of the experiment was 36.0 % lower in the LN treatment than in the CF treatment (P?<?0.05). Our results suggest that lime-N application decreases N₂O emission by inhibiting both nitrification and denitrification processes in the acidic soil.     

Leaf turnover and growth responses of shade-grown saplings of four Shorea rain forest species to a sudden increase in light

We tested the hypothesis that sapling growth following a sudden increase in solar irradiance is related to recovery from photoinhibition and the balance between rate of production of new leaves and rate of abscision of old leaves. Leaf gas exchange, chlorophyll fluorescence and relative growth rate (RGR) of stem basal area were measured following the sudden exposure of shade-grown (7% of full sunlight) saplings of four Shorea species to full sunlight. Sudden exposure to full sunlight resulted in an immediate and substantial reduction in dark-adapted quantum yield of photosystem II (Fv/Fm), followed by a gradual recovery in all species. Near light-saturated net assimilation rate (A max) and area-based leaf chlorophyll concentration ([Chl area]) also declined immediately after exposure. Eleven days after exposure, A max had recovered to pre-exposure values in all species, whereas [Chl area] had not recovered. Across species, RGR of stem basal area increased with increasing RGR of the number of leaves following exposure to full sunlight. The interspecific variations in RGR of stem basal area suggest that new leaf production is crucial for determining the potential growth of saplings following gap formation.