Many thousands of recombinant proteins have been successfully produced in baculovirus - infected insect cells and larvae. In this study, to improve its value and the yield of recombinant protein production, we constructed transgenic silkworm using Heat shock genes with regard to protein folding. This time, we adapted GAL4/UAS system to express at necessary time point and to carry genes for foreign protein. First, we generated two transgenic cells and silkworm lines that carried the silkworm heat shock proteins, UAS-HOP and UAS-HSC70 and UAS-HSP70 and UAS-HSP40 construct plus 3xP3-DsRED. Subsequently, to drive the GAL4 gene as activatorvector, we engineered Baculoviruses that contain the GAL4 under the P10 promoter linked to the expression cassette of interest foreign genes under the polyhedron promoter. Also, activator vector linked to the GAL4 was designed expressing 6xHis and 6xHis–GST tag. Infection of silkworm larvae with recombinant virus, His-tagged human C3d gene was more efficiently produced transgenic silkworm than that of wild-type, but not His-GST tagged. We show the possibilityin use of HSPs transgenic silkworm system by GAL4/ UAS BmNPV that can generate the efficient production of foreign protein.
This study was conducted to analyze seasonal variations of de-icing salt ions harvested from soils and plants according to salt damage of Pinus densiflora f. multicaulis, a evergreen conifer, on roadsides. Pinus densiflora f. multicaulis was divided into three groups referred to SD, ND, and WD (serious salt damage (SD) = 71 100%, normal salt damage (ND) = 31 70%, and weak salt damage (WD) = 0 30%) based on the degree of visible foliage damage, and measured acidity (pH), electrical conductivity(EC), and de-icing salt ions (K+, Ca2+, Na+, and Mg2+) harvested from soils and plants. The results indicated that acidity, electrical conductivity, and de-icing salt ions of soils and plants were significantly affected by seasonal variation and salt damage. In addition, a strong positive liner relationship was observed in plants between the concentration of de-icing salts and salt damage in spring, while the relationship among seasonal variation and salt damage in soil were not significant. The results from this study has important implications for the management of conifer species in relation to salinity and roadsides maintenance.
This study aims to identify the most tolerant species under salinity stress from amongst Asteraceae and Poaceae. The seeds of six species were exposed to different concentrations of CaCl2 (0, 9, 18, 45, 90 mM) and NaCl (0, 17, 34, 85, 170 mM), and germination was measured once every two days. The results indicated that percent germination of the six species of Asteraceae and Poaceae seeds were affected differently by changes in salinity concentration. Seed germination was reduced as salinity levels increase, and longer mean germination times correlated to lower percent germination and earlier germination cessation. Both Asteraceae and Poaceae seeds had the highest germination rates at 18 mM CaCl2 and 34 mM NaCl, and seed germination and growth were severely reduced at salinities greater than 90 mM CaCl2 and 170 mM NaCl. In the seeds of Poaceae, salt resistance was strong in the order of Miscanthus sinensis Andersson, Pennisetum alopecuroides (L.) Spreng., and Phragmites communis Trin. In the seeds of Asteraceae, salt resistance was strong in the order of Dendranthema zawadskii var. latilobum (Maxim.) Kitam, Aster yomena (Kitam.) Honda, and Dendranthema boreale (Makino) Ling ex Kitam.. Overall, the germination rate was higher in Asteraceae than in Poaceae. This study demonstrated that Dendranthema zawadskii var. latilobum (Maxim.) Kitam. is the most tolerant species and that a relationship exists between the salt tolerance of percent germination and the mean germination time in the leaves.
Tropaeolum majus, with a high decorative and food demand for vertical greening systems, has been utilized to revitalize urban agriculture. The effects of number of non-woven fabrics in a non-water environment and the adaptability of T. majus to this system were investigated. Planting ground composition of the container-type wall vertical greening system was made using non-woven fabric in one, two, three, or four layers. The results showed that the soil water content remained the highest when the non-woven fabric comprised 4 sheets. The morphological properties showed more growth with the 4 sheets than with 1, 2, and 3 sheets. In terms of physiological characteristics, chlorophyll content was mostly high in the 4 sheets, while shoot fresh weight value was in the order of 3 sheets > 4 sheets > 2 sheets > 1 sheet, and root fresh weight value was in the order of 4 sheets > 2 sheets > 1 sheet > 3 sheets. The dry weight of the measured values in the shoot was in the order of 4 sheets > 3 sheets > 2 sheets > 1 sheet while no clear difference was found in the root of each treatment. The difference in the flowring characteristics was not different, but in evaluating the characteristics as a whole, the growth in the three layers of non-waven fabric was the best. In addition, the soil moisture content and the growth characteristics were statistically significant as a positive correlation between the groups. Thus, greater the non-woven fabric, the higher is the adaptability of T. majus to dry stress under soil water-free conditions by maintaining soil moisture content. This showed that it represented an effective alternative as a method of vertical greening system for lower maintenance urban agriculture.