aureus
against Dictyostelium discoideum phagocytosis in co-culture biofilms.”
“We fabricated Pt-containing granular metals by focused electron beam-induced deposition from the (CH3)(3)CH3C5H4Pt precursor gas. The granular metals are made of platinum nanocrystallites embedded in a carbonaceous matrix. We exposed the as-grown nanocomposites to low-energy electron beam irradiation and measured the electrical conductivity as a function of irradiation dose. Postgrowth electron beam irradiation transforms the matrix microstructure and thus the strength of the tunneling coupling between Pt nanocrystallites. For as-grown samples (weak tunnel coupling regime) we GW4869 mouse find that the temperature dependence of the electrical
conductivity follows the stretched exponential behavior characteristic of the correlated variable-range hopping transport regime. For briefly irradiated samples (strong tunnel coupling regime) the electrical conductivity is tuned across the metal-insulator transition. For long-time irradiated samples the electrical conductivity behaves like that of a metal. In order to further analyze DMXAA in vitro changes of the microstructure as a function of the electron irradiation dose, we carried out transmission electron microscope (TEM), micro-Raman spectroscopy, and atomic force microscopy (AFM) investigations. TEM pictures reveal that crystallite size in long-time irradiated samples is larger than that in as-grown samples. Furthermore, we do not have evidence of microstructural changes in briefly irradiated samples. By means of micro-Raman spectroscopy we find that by increasing the irradiation dose the matrix changes, following a graphitization trajectory between amorphous carbon and nanocrystalline graphite. Finally, by means of AFM measurements we observe a reduction of the volume of the samples with increasing irradiation time, which we attribute to the removal FDA-approved Drug Library cell assay of carbon molecules. (C) 2011 American Institute of Physics. [doi: 10.1063/1.3559773]“
“Expression of FLOWERING LOCUS T (FT) and its homologues has been shown to accelerate the onset
of flowering in a number of plant species, including poplar (Populus spp.). The application of FT should be of particular use in forest trees, as it could greatly accelerate and enable new kinds of breeding and research. Recent evidence showing the extent to which FT is effective in promoting flowering in trees is discussed, and its effectiveness in poplar is reported. Results using one FT gene from Arabidopsis and two from poplar, all driven by a heat-inducible promoter, transformed into two poplar genotypes are also described. Substantial variation in flowering response was observed depending on the FT gene and genetic background. Heat-induced plants shorter than 30 cm failed to flower as well as taller plants.
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