Artificial Intelligence–Enabled Analysis of Public Attitudes on Facebook and Twitter Toward COVID-19 Vaccines in the United Kingdom and the United States: Observational Study

In this work, we have studied, by means of Raman spectroscopy, water-additives interactions in the case of alkaline halogenides aqueous solutions. We have obtained some parameters describing the evolution of water structure vs concentration or the nature of the added salts. These parameters show, as previously described, a more important effect of anions than cations. Next, the evolution of the dynamical properties of the solution depends on the size of the ions. Moreover, the development of a new band in the isotropic part of the salts solutions spectra is attributed to water–ions interactions involved in the dynamics of hydration shells.

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Light controls shoot meristem organogenic activity and leaf primordia growth during bud burst in Rosa sp.

Girault

Bergougnoux

Combes

et al. 2008

Plant Cell & Environment

113

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Light controls bud burst in many plants, which subsequently affects their architecture. Nevertheless, very little is known about this photomorphogenic process. This study ascertains the effects of light on bud burst and on two of its components, i.e. growth of preformed leaves and meristem organogenesis in six cultivars from three Rosa species (R. hybrida L., R. chinensis L., R. wichurana L.). Defoliated plants were severed above the third basal bud and exposed, either to darkness or to different intensities of white light, to blue, red or to FR, at constant temperature. Bud bursting was inhibited in darkness in the six cultivars of Rosa, but not in Arabidopsis, tomato and poplar plants under the same condition. In all Rosa cultivars, bud burst, growth of preformed leaves and meristem organogenesis were triggered by blue and red lights, and extended by increasing light intensities. FR was inhibitory of bud burst. Partial shading experiments demonstrated that bud and not stem was the active site for light perception in bud burst.

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Lipase-catalysed transesterification of high oleic sunflower oil

Dossat

Combes

Marty

2002

Enzyme and Microbial Technology

166

100

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Four Genes Encode Acetylcholinesterases in the Nematodes Caenorhabditis elegans and Caenorhabditis briggsae. cDNA Sequences, Genomic Structures, Mutations and in vivo Expression

Combes

Fédon

Grauso

et al. 2000

Journal of Molecular Biology

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Effects of commercial enzymes on the adhesion of a marine biofilm-forming bacterium

et al. 2008

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The antifouling potential of commercial hydrolases, four proteases, seven glycosidases and one lipase was evaluated on the adhesion of marine Pseudoalteromonas sp. D41. The experimental method, adapted to screen antifouling agents, was based on bacterial adhesion in natural sterile sea water in a microtiter plate and on total biomass quantification by the fluorescent dye DAPI (4[prime]6-diamidino-2-phenylindole). Savinase (subtilisin) was the most effective hydrolase in both the prevention of bacterial adhesion and the removal of adhered bacteria. However, some enzymatic preparations tested such as Amano protease were not only ineffective but also increased the number of adhered bacterial cells. Enumeration using epifluorescence microscopy of CTC (5-cyano-2,3-ditolyl tetrazolium chloride) and DAPI stained adhered D41 cells confirmed these observations. Overall, these results demonstrated that hydrolases could either prevent adhesion and remove adhered bacterial cells effectively, or conversely increase bacterial adhesion, depending on enzymatic concentrations and the type of enzymes tested.

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Regional climate modulates the canopy mosaic of favourable and risky microclimates for insects

Pincebourde

Sinoquet

Combes

et al. 2007

Journal of Animal Ecology

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Summary 1.One major gap in our ability to predict the impacts of climate change is a quantitative analysis of temperatures experienced by organisms under natural conditions. We developed a framework to describe and quantify the impacts of local climate on the mosaic of microclimates and physiological states of insects within tree canopies. This approach was applied to a leaf mining moth feeding on apple leaf tissues. 2. Canopy geometry was explicitly considered by mapping the 3D position and orientation of more than 26 000 leaves in an apple tree. Four published models for canopy radiation interception, energy budget of leaves and mines, body temperature and developmental rate of the leaf miner were integrated. Model predictions were compared with actual microclimate temperatures. The biophysical model accurately predicted temperature within mines at different positions within the tree crown. 3. Field temperature measurements indicated that leaf and mine temperature patterns differ according to the regional climatic conditions (cloudy or sunny) and depending on their location within the canopy. Mines in the sun can be warmer than those in the shade by several degrees and the heterogeneity of mine temperature was incremented by 120%, compared with that of leaf temperature. 4 . The integrated model was used to explore the impact of both warm and exceptionally hot climatic conditions recorded during a heat wave on the microclimate heterogeneity at canopy scale. During warm conditions, larvae in sunlight-exposed mines experienced nearly optimal growth conditions compared with those within shaded mines. The developmental rate was increased by almost 50% in the sunny microhabitat compared with the shaded location. Larvae, however, experienced optimal temperatures for their development inside shaded mines during extreme climatic conditions, whereas larvae in exposed mines were overheating, leading to major risks of mortality. 5. Tree canopies act as both magnifiers and reducers of the climatic regime experienced in open air outside canopies. Favourable and risky spots within the canopy do change as a function of the climatic conditions at the regional scale. The shifting nature of the mosaic of suitable and risky habitats may explain the observed uniform distribution of leaf miners within tree canopies.

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Geranyl acetate synthesis by lipase-catalyzed transesterification in supercritical carbon dioxide

Chulalaksananukul

Condoret

Combes

1993

Enzyme and Microbial Technology

140

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Didier Combes

Continuous enzymatic transesterification of high oleic sunflower oil in a packed bed reactor: influence of the glycerol production

Effect of salts on dynamics of water: A Raman spectroscopy study

Light controls shoot meristem organogenic activity and leaf primordia growth during bud burst in Rosa sp.

Lipase-catalysed transesterification of high oleic sunflower oil

Four Genes Encode Acetylcholinesterases in the Nematodes Caenorhabditis elegans and Caenorhabditis briggsae. cDNA Sequences, Genomic Structures, Mutations and in vivo Expression

Effects of commercial enzymes on the adhesion of a marine biofilm-forming bacterium

Regional climate modulates the canopy mosaic of favourable and risky microclimates for insects

Geranyl acetate synthesis by lipase-catalyzed transesterification in supercritical carbon dioxide

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