Your search keyword '"Streibig JC"' showing total 3 results

1. Functional regression analysis of fluorescence curves.

Author

Ritz C and Streibig JC

Subjects

Chlorophyll A, Algorithms, Chlorophyll analysis, Data Interpretation, Statistical, Photosynthesis physiology, Regression Analysis, Spectrometry, Fluorescence methods

Abstract

Summary: Fluorescence curves are useful for monitoring changes in photosynthesis activity. Various summary measures have been used to quantify differences among fluorescence curves corresponding to different treatments, but these approaches may forfeit valuable information. As each individual fluorescence curve is a functional observation, it is natural to consider a functional regression model. The proposed model consists of a nonparametric component capturing the general form of the curves and a semiparametric component describing the differences among treatments and allowing comparisons of treatments. Several graphical model-checking approaches are introduced. Both approximate, asymptotic confidence intervals as well as simulation-based confidence intervals are available. Analysis of data from a crop experiment using the proposed model shows that the salient features in the fluorescence curves are captured adequately. The proposed functional regression model is useful for analysis of high throughput fluorescence curve data from regular monitoring or screening of plant growth.

Published

2009

2. Does the effect of herbicide pulse exposure on aquatic plants depend on Kow or mode of action?

Author

Cedergreen N, Andersen L, Olesen CF, Spliid HH, and Streibig JC

Subjects

Aniline Compounds toxicity, Araceae growth & development, Arylsulfonates toxicity, Benzamides toxicity, Chlorophyll metabolism, Chromatography, Liquid, Diquat toxicity, Dose-Response Relationship, Drug, Fluorescence, Fresh Water, Imidazoles toxicity, Mass Spectrometry, Time Factors, Triazines toxicity, Araceae drug effects, Herbicides toxicity, Photosynthesis drug effects

Abstract

The highest concentrations of herbicides measured in flowing surface waters are often only present for short periods of time. These herbicide pulses can reach concentrations that would affect aquatic plants if present over a long time. The aim of this study was to assess the effect of a 3-h herbicide pulse relative to the effects of long-term (4 and 7 days) exposure of six herbicides with different sites of action and different K(ow) on the growth of the floating macrophyte Lemna minor. The herbicides were the two photosynthetic inhibitors: diquat and terbuthylazine, the inhibitors of acetolactate syntase (ALS), imazamox and metsulfuron-methyl and the microtubule assembly inhibitors propyzamide and pendimethalin. The log K(ow) ranged from -4.6 to 5.2. For imazamox, metsulfuron-methyl, propyzamide and pendimethalin a 3-h pulse induced the effect on area-specific growth as did a 4-day exposure at an approximate 10-fold higher concentration. For diquat and terbuthylazine a concentration closer to a factor of 100 or more was needed for a 3-h pulse to induce an effect similar to that of a 4-day exposure. For diquat, the low pulse-effect was most likely due to a slow uptake of the hydrophilic ion (log K(ow) = -4.6), as no effect was observed on chlorophyll fluorescence within 8 h after exposure. The chlorophyll fluorescence parameters are expected to respond quickly to a PSI inhibitor as diquat. For terbuthylazine, fluorescence measurements showed an effect on photosynthesis within 1h of exposure, and reached a minimum after 3 h. Recovery was fast, and initial fluorescence was restored within 24 h. Hence, the small pulse effect on area-specific growth was due to rapid recovery of photosynthesis. In contrast to terbuthylazine, the stop in area-specific growth observed for the ALS-and microtubule assembly inhibitors, took up to 4 days to recover from. Such a long recovery time after a pulse of only 3 h indicate that at realistic pulse exposures of up to a day or two, pulse-effects will approach the effects obtained in long-term studies. When investigating the effects of pulse exposures on aquatic plants, we should therefore focus more on non-photosynthetic inhibitors, which might not appear in pulses in as large concentrations as the PSII inhibitors investigated up till now, but whose effect, even in a shorter pulse, can be more damaging.

Published

2005

3. PSII inhibitory activity of resorcinolic lipids from Sorghum bicolor.

Author

Rimando AM, Dayan FE, and Streibig JC

Subjects

Algorithms, Chlorophyll metabolism, Germination drug effects, Inhibitory Concentration 50, Lactuca drug effects, Light-Harvesting Protein Complexes, Lipids chemistry, Lipids pharmacology, Molecular Structure, Nuclear Magnetic Resonance, Biomolecular, Photosynthetic Reaction Center Complex Proteins chemistry, Photosystem II Protein Complex, Plant Roots chemistry, Quinones metabolism, Resorcinols chemistry, Resorcinols pharmacology, Stereoisomerism, Lipids isolation & purification, Photosynthesis drug effects, Photosynthetic Reaction Center Complex Proteins metabolism, Poaceae chemistry, Resorcinols isolation & purification

Abstract

Resorcinolic lipids were isolated from the root extracts of Sorghum bicolor and identified as 4,6-dimethoxy-2-[(8'Z,11'Z)-8',11',14'-pentadecatriene]resorcinol (4), 4-methoxy-6-ethoxy-2-[(8'Z,11'Z)-8',11',14'-pentadecatriene]resorcinol (5), and 4-hydroxy-6-ethoxy-2-[(10'Z,13'Z)-10',13',16'-heptadecatriene]resorcinol (6). Compounds 4 and 5 inhibited photosynthetic oxygen evolution (IC50 0.09 and 0.20 microM, respectively). Compound 4 could not be enzymatically converted to a quinone, suggesting that the quinone moiety is not required for its photosystem II inhibitory activity. Compounds 5 and 6 are reported for the first time.

Published

2003