The rapid increase in the number and volume of chemical substances being used in modern society has been accompanied by a large number of potentially hazardous chemicals being found in environmental samples. In Vietnam, the monitoring of chemical substances is mainly limited to a small number of known pollutants in spite of rapid economic growth and urbanization, and there is an urgent need to examine a large number of chemicals to prevent impacts from expanding environmental pollution. However, it is difficult to analyze a large number of chemicals using existing methods, because they are time consuming and expensive. In the present study, we determined 1153 substances to grasp a pollution picture of microcontaminants in the aquatic environment. To achieve this objective, we have used two comprehensive analytical methods: (1) solid-phase extraction (SPE) and LC-TOF-MS analysis, and (2) SPE and GC-MS analysis. We collected 42 samples from northern (the Red River and Hanoi), central (Hue and Danang), and southern (Ho Chi Minh City and Saigon-Dongnai River) Vietnam. One hundred and sixty-five compounds were detected at least once. The compounds detected most frequently (>40 % samples) at μg/L concentrations were sterols (cholesterol, beta-sitosterol, stigmasterol, coprostanol), phthalates (bis(2-ethylhexyl) phthalate and di-n-butyl phthalate), and pharmaceutical and personal care products (caffeine, metformin). These contaminants were detected at almost the same detection frequency as in developed countries. The results reveal that surface waters in Vietnam, particularly in the center of large cities, are polluted by a large number of organic micropollutants, with households and business activities as the major sources. In addition, risk quotients (MEC/PNEC values) for nonylphenol, sulfamethoxazole, ampicillin, acetaminophen, erythromycin and clarithromycin were higher than 1, which indicates a possibility of adverse effects on aquatic ecosystems.
SummaryPartial desiccation treatment (PDT) stimulates germination and enhances the conversion of conifer somatic embryos. To better understand the mechanisms underlying the responses of somatic embryos to PDT, we used proteomic and physiological analyses to investigate these responses during PDT in Picea asperata. Comparative proteomic analysis revealed that, during PDT, stress‐related proteins were mainly involved in osmosis, endogenous hormones, antioxidative proteins, molecular chaperones and defence‐related proteins. Compared with those in cotyledonary embryos before PDT, these stress‐related proteins remained at high levels on days 7 (D7) and 14 (D14) of PDT. The proteins that differentially accumulated in the somatic embryos on D7 were mapped to stress and/or stimuli. They may also be involved in the glyoxylate cycle and the chitin metabolic process. The most significant difference in the differentially accumulated proteins occurred in the metabolic pathways of photosynthesis on D14. Furthermore, in accordance with the changes in stress‐related proteins, analyses of changes in water content, abscisic acid, indoleacetic acid and H2O2 levels in the embryos indicated that PDT is involved in water‐deficit tolerance and affects endogenous hormones. Our results provide insight into the mechanisms responsible for the transition from morphologically mature to physiologically mature somatic embryos during the PDT process in P. asperata.
Cryopreservation of embryogenic tissue is an essential storage step in genotype selection and seedling production through somatic embryogenesis. To date, immature conifer somatic embryos, at the proliferation step, were only able to tolerate ultra low temperature after prior cryoprotectant treatments. We report a novel cryopreservation method for conifer (interior spruce and Douglas-fir) embryogenic tissue focusing on the maturation step of developing embryos that forgoes such cryoprotectant treatment. In this study, somatic embryos matured on culture media containing abscisic acid (ABA) at 20°C for 8 weeks. Typically, matured embryos in this manner were able to survive cryopreservation. The embryogenicity, however, decreased with increasing embryo maturity. Nonfreezing low temperatures, such as 5°C, not only inhibited cotyledon development but also maintained embryogenicity. Cryotolerance was successfully induced when embryos were matured (or pretreated) under 5°C for a suitable culture period, typically 4-8 weeks. These embryos were able to survive a rapid cooling process and liquid nitrogen storage without the addition of any cryoprotectants. After cryopreservation, embryogenic tissue was recovered in both interior spruce and Douglas-fir. Embryo maturation tests indicated no difference in mature embryo yields with or without cryopreservation in interior spruce. The key factors inducing cryotolerance included ABA supplementation in culture media and low temperature pretreatment. Optimum combinations of these factors can result in high rates of tissue survival and high embryogenicity after cryopreservation.
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