Spiraea prunifolia leaves extract inhibits adipogenesis and lipogenesis by promoting ß-oxidation in high fat diet-induced obese mice.

Spiraea prunifolia has been used in Korean traditional medicine to treat malaria, fever, and emetic conditions. Previous investigation reported that several parts of Spiraea prunifolia show various functional effects. However, the effect of Spiraea prunifolia leaves extract (SPE) on anti-obesity remains unclear. Therefore, we used a high-fat diet (HFD)-induced obese mouse model in this study to investigate the effects of SPE on adipogenesis, lipogenesis, and ß-oxidation. Oral administration of SPE in HFD-induced obese mice considerably reduced body weight, serum levels such as total cholesterol, triglyceride, high-density lipoprotein cholesterol, and low-density lipoprotein cholesterol, adipose tissue weight, and adipocyte cell size. Moreover, SPE significantly decreased protein expression levels of adipogenesis and lipogenesis related genes such as CCAAT/enhancer binding protein α, peroxisome proliferator-activated receptor γ, adipocyte protein 2, acetyl-CoA carboxylase, and fatty acid synthase in epididymal adipose tissues. SPE treatment induced the protein expression of carnitine palmitoyl transferase-1, which might have promoted phosphorylated AMP-activated protein kinase-medicated ß-oxidation. The present study reveals an anti-adipogenic, anti-lipogenic, ß-oxidation effects of SPE in vivo and represents AMP-activated protein kinase signaling as targets for SPE.

SfGPX regulates low-temperature tolerance by affecting velocity and intensity of Ca2+ transfer and photosynthetic characteristics in interfered Spiraea fritschiana and overexpressed Spiraea japonica 'Gold Mound'.

Genes play regulatory roles in plants' response to low-temperature stress. Our understanding of the mechanism of plants' response to low-temperature stress can be expanded by studying the functions of these genes. SfGPX was cloned from Spiraea fritschiana (S. fritschiana) with the highest low-temperature tolerance, to explore the molecular mechanisms of SfGPX in response to low-temperature stress and the physiological mechanisms involved in the regulation of SfGPX to adapt to low temperature, in two species of Spiraea. SfGPX, which was localized in the cytoplasm, was induced by low temperature. The low-temperature tolerance of Spiraea fritschiana was decreased via the interference of SfGPX, and the low-temperature tolerance of Spiraea japonica 'Gold Mound' (S. japonica 'Gold Mound') was elevated via the overexpression of SfGPX. Under low-temperature stress, the photosynthetic capacity of two species of Spiraea was affected by SfGPX; it was higher in the cold-tolerant plants and lower in the cold-intolerant plants. Under low-temperature stress, the transfer intensity of Ca2+ was affected by SfGPX. The transfer intensity of cold-tolerant plants with lower influx level of Ca2+ kinetics was weaker than that of cold-intolerant plants. Under low-temperature stress, the transfer velocity of Ca2+ was affected by SfGPX, and there were slower effluxes of Ca2+ from Ca2+ reservoir in cold-tolerant plants than in cold-intolerant plants. The above results indicate that the response of Spiraea to low temperature is regulated by SfGPX through affecting photosynthetic capacity as well as intensity and velocity of Ca2+ transfer in response to low temperature in Spiraea.

Enhancing stress growth traits as well as phytochemical and antioxidant contents of Spiraea and Pittosporum under seaweed extract treatments.

Seaweed extracts (SWE) might play an important role in enhancing growth and phytochemical composition of medicinal shrubs. In this study, we investigate the morphological, physiological and biochemical effects of irrigation levels (100% and 50% of the evapotranspiration rate) coupled with a weekly treatment of SWE of Ascophyllum nodosum at 5 and 7 mL L(-1) as a soil drench or foliar spray on Spiraea nipponica "Snowmound" and Pittosporum eugenioides "Variegatum" grown in containers under controlled greenhouse conditions. In addition, the phenolic and flavonoid content, antioxidant capacity and lipid peroxidation in both plant species was largely enhanced while the proline accumulation was reduced. After 8 weeks of treatments, drought condition reduced plant vegetative growth and gas exchange, as well as leaf water potential, but increased the phenolic and flavonoid contents in leaves, their antioxidant capacities and proline content. The application of SWE enhanced the performance of both species during mild drought conditions by means of increasing leaf number and area, dry weights, plant height, gas exchange and leaf water potential. The maximum vegetative growth, physiological performance and phytochemical composition of both species was achieved using the drench SWE treatments (5 and 7 mL L(-1)) in moderate drought conditions, which improved the plant water status, stomatal conductance, and photosynthetic rate. SWE enhanced plant growth and the phytochemical composition and antioxidant capacity of plant leaves of both species during moderate drought conditions.

Comparing the influence of wildfire and prescribed burns on watershed nitrogen biogeochemistry using 15N natural abundance in terrestrial and aquatic ecosystem components.

We evaluated differences in the effects of three low-severity spring prescribed burns and four wildfires on nitrogen (N) biogeochemistry in Rocky Mountain headwater watersheds. We compared paired (burned/unburned) watersheds of four wildfires and three spring prescribed burns for three growing seasons post-fire. To better understand fire effects on the entire watershed ecosystem, we measured N concentrations and δ15N in both the terrestrial and aquatic ecosystems components, i.e., soil, understory plants in upland and riparian areas, streamwater, and in-stream moss. In addition, we measured nitrate reductase activity in foliage of Spiraea betulifolia, a dominant understory species. We found increases of δ15N and N concentrations in both terrestrial and aquatic ecosystem N pools after wildfire, but responses were limited to terrestrial N pools after prescribed burns indicating that N transfer from terrestrial to aquatic ecosystem components did not occur in low-severity prescribed burns. Foliar δ15N differed between wildfire and prescribed burn sites; the δ15N of foliage of upland plants was enriched by 2.9 ‰ (difference between burned and unburned watersheds) in the first two years after wildfire, but only 1.3 ‰ after prescribed burns. In-stream moss δ15N in wildfire-burned watersheds was enriched by 1.3 ‰, but there was no response by moss in prescription-burned watersheds, mirroring patterns of streamwater nitrate concentrations. S. betulifolia showed significantly higher nitrate reductase activity two years after wildfires relative to corresponding unburned watersheds, but no such difference was found after prescribed burns. These responses are consistent with less altered N biogeochemistry after prescribed burns relative to wildfire. We concluded that δ15N values in terrestrial and aquatic plants and streamwater nitrate concentrations after fire can be useful indicators of the magnitude and duration of fire effects and the fate of post-fire available N.

Protein expression patterns in two Spiraea species in response to cold treatment.

We analyzed the different cold-resistance species Spiraea trichocarpa Nakai and Spiraea bumalda 'Goldmound' for low-temperature protein expression, protein types identification, and investigated the cold resistance mechanisms under different levels of low temperature by two-dimensional gel electrophoresis (2-DE) and mass spectrometry. An average of 668 and 559 protein spots were detected by 2-DE of S. bumalda 'Goldmound' and S. trichocarpa Nakai, respectively, under different low-temperature treatments. Matrix-assisted laser desorption/ionization time-of-flight mass spectroscopy identified 48 proteins, with varying expression, related to metabolism, amino acid synthesis, transportation, stress responses and oxidation-reduction reactions. The results showed that the photosynthesis of S. bumalda 'Goldmound' had been affected, enzymes (RuBisCO large and small subunits) involved in the Calvin cycle were up- and down-regulated, and ATP synthase in photophosphorylation was down-regulated. Cytosolic malate dehydrogenase expression weakened in the TCA cycle, while amino acid synthesis strengthened. The activity of four antioxidant enzymes (superoxide dismutase [Cu-Zn], L-ascorbate peroxidase, glutathione peroxidase and peroxidase) was reduced under varying low temperatures. Enzymes (ribulose-bisphosphate carboxylase and RuBisCO small chain precursor) involved in the photosynthesis of S. trichocarpa Nakai showed obvious up- and down-regulation under low temperatures. Cold treatment influenced the photosynthesis of S. trichocarpa Nakai and S. bumalda 'Goldmound', but the results showed significant differences between the two species, which were supposed to the fact that low temperature modified the metabolic mechanisms and led to the weaker cold resistance in S. bumalda 'Goldmound' than in S. trichocarpa Nakai.