95 3 95 M TE) and was stronger compared to the control Hyperoside

95 3.95 M TE) and was stronger compared to the control Hyperoside (421.75 9.29 M TE). Elegaphenone and 7-Epiclusianone were found to possess moderate acetyl cholinesterase inhibitory

potential with IC 50 values of 192.19 3.54 M and 142.97 4.62 M, respectively. Conclusion: The results obtained revealed that H. elegans is a potential natural source of bioactive compounds and benzophenones could be useful in therapy of free radical pathologies and neurodegenerative disorders.”
“Seasonal variability of maximum quantum yield of PSII photochemistry (F(v)/F(m)) was studied in needles of Taxus baccata seedlings acclimated Citarinostat datasheet to full light (HL, 100% solar irradiance), medium light (ML, 18% irradiance) or low light (LL, 5% irradiance). In HL plants, F(v)/F(m) was below 0.8 (i.e. state of photoinhibition) throughout the whole experimental period from November to May, with the greatest decline Smoothened Agonist mouse in January and February (when F(v)/F(m) value reached 0.37). In ML seedlings, significant declines of F(v)/F(m) occurred in January (with the lowest level at 0.666), whereas the decline in LL seedlings (down to 0.750) was not significant. Full recovery of F(v)/F(m) in HL seedlings was delayed until the end of May, in contrast to ML and

LL seedlings. F(v)/F(m) was significantly correlated with daily mean (T (mean)), maximal (T (max)) and minimal (T (min)) temperature and T (min) was consistently the best predictor of F(v)/F(m) in HL and ML needles. Temperature averages obtained over 3 or 5 days prior to measurement were better predictors of F(v)/F(m) than 1- or 30-day averages. Thus our results indicate a strong light-dependent seasonal photoinhibition in needles of T. baccata TPX-0005 chemical structure as well as suggest a coupling of F(v)/F(m) to cumulative temperature from several preceding days. The dependence of sustained winter photoinhibition on light level to which the plants are acclimated was further demonstrated when plants from the

three light environments were exposed to full daylight over single days in December, February and April and F(v)/F(m) was followed throughout the day to determine residual sensitivity of electron transport to ambient irradiance. In February, the treatment revealed a considerable midday increase in photoinhibition in ML plants, much less in HL (already downregulated) and none in LL plants. This suggested a greater capacity for photosynthetic utilization of electrons in LL plants and a readiness for rapid induction of photoinhibition in ML plants. Further differences between plants acclimated to contrasting light regimes were revealed during springtime de-acclimation, when short term regeneration dynamics of F(v)/F(m) and the relaxation of nonphotochemical quenching (NPQ) indicated a stronger persistent thermal mechanism for energy dissipation in HL plants.

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