Cell Death Induced on Cell Cultures and Nude Mouse Skin by Non-Thermal,Nanosecond-Pulsed Generated Plasma

Non-thermal plasmas are gaseous mixtures of molecules, radicals, and excited species with a small proportion of ions and energetic electrons. Non-thermal plasmas can be generated with any high electro-magnetic field. We studied here the pathological effects, and in particular cell death, induced by nanosecond-pulsed high voltage generated plasmas homogeneously applied on cell cultures and nude mouse skin. In vitro, Jurkat cells and HMEC exhibited apoptosis and necrosis, in dose-dependent manner. In vivo, on nude mouse skin, cell death occurred for doses above 113 J/cm² for the epidermis, 281 J/cm² for the dermis, and 394 J/cm² for the hypodermis. Using electron microscopy, we characterized apoptosis for low doses and necrosis for high doses. We demonstrated that these effects were not related to thermal, photonic or pH variations, and were due to the production of free radicals. The ability of cold plasmas to generate apoptosis on cells in suspension and, without any sensitizer, on precise skin areas, opens new fields of application in dermatology for extracorporeal blood cell treatment and the eradication of superficial skin lesions.     

Visualization of ribosomal DNA loci in spore interphasic nuclei of glomalean fungi by fluorescence in situ hybridization

 Fluorescence in situ hybridization (FISH) was applied to interphasic nuclei isolated from spores of four species of AM fungi : Scutellospora castanea, Glomus mosseae, Glomus intraradices and Gigaspora rosea. Ribosomal DNA loci were visualized using digoxigenin-labeled 25 S rDNA probes obtained by nested PCR. Several hybridization sites were detected per nucleus and an internuclear variability was observed in the number of loci. This is the first report of successful application of FISH to analyse the genomes of glomalean fungi. Accepted: 16 September 1998     

Subunit organization of PSI particles from brown algae and diatoms: polypeptide and pigment analysis

P700 enriched fractions were isolated from two brown algae and one diatom using sucrose density centrifugation after digitinin solubilization. They had a Chl a/P700 ratio of about 250 to 375 according to the species, they were enriched in long-wavelength absorbing Chl a and exhibited a fluorescence emission maximum at 77 K near 720 nm. They all presented a major polypeptide component at 66±2 kDa, but their polypeptide composition was rather complex and somewhat different from one species to another. Further solubilization with dodecylmaltoside of those native PSI particles allowed the separation of two or three fractions. The lightest, xanthophyll-rich, fraction was identified to be a light-harvesting complex. It contained no P700 and had a major polypeptide of molecular weight near 20 kDa (at the same molecular weight than the respective LH native fraction of each species) and exhibited a 77 K peak fluorescence emission at 685 nm. The other fractions were enriched in P700 and almost entirely depleted in xanthophylls. When two of them are present, they both exhibited a major polypeptide at 66±2 kDa and were totally devoid of the LH polypeptide, but the two fractions widely differed one from another in the abundance and molecular weight of the other polypeptide components. The most purified of these two fractions presented a composition similar to PSI core complex from green plants.Abbreviations LH light-harvesting - LHCII light-harvesting complex II of green plants - P700 reaction center chlorophyll of PSI     

Resonance Raman Spectra of Photodissociated Hemoglobins: Implications on Cooperative Mechanisms

Resonance Raman spectra at cryogenic temperatures of photodissociated hemoglobins and the corresponding deoxygenated preparations are compared and significant differences are found in modes with contributions from peripheral substituents of the heme as well as in the iron-histidine stretching mode. These differences in heme vibrational spectra reflect differences in the tertiary structure of the heme pocket between deoxyhemoglobin and the CO-bound form. An analysis of the effects of cooperative energy storage on the tertiary structure around the heme is made and used to interpret this resonance Raman data. The differences between the spectra of the deoxygenated preparations and the photoproducts provide evidence that a fraction of the free energy of cooperativity, ΔG, is located away from the heme. These data support models for cooperativity in which the cooperative energy is distributed over many bonds or is localized in protein bonds only, such as those at the subunit interface. In addition, the local changes in amino acid positions, which must occur following the change in the state of ligand binding, may drive the changes in the structural relationships of the subunits and hence form one of the initial steps for triggering the quaternary structure transition.     

Fuel ethanol from corn residue prehydrolysate by a patented ethanologenicEscherichia coli B

Summary The hemicellulose component of corn cobs was completely hydrolyzed by treatment with dilute sulphuric acid. HPLC analysis showed the prehydrolysate to contain 36g/L xylose; 7g/L arabinose; 6g/L glucose and 4.2g/L acetic acid. The patented genetically engineered ethanologenEscherichia coli B (ATCC 11303 pLOI 297) exhibited high performance characteristics with a synthetic model medium in which the pH was controlled at 7 in order to minimize sensitivity to acetic acid. With the synthetic medium, fermentation was completed in 36h and the process yield was 0.49g/g, equivalent to 96% max. theoretical conversion efficiency. However, with the supplemented corn cob prehydrolysate medium, about 20% of the sugar remained unfermented after 8 days, with a conversion efficiency of <40%. Treatment of the prehydrolysate with calcium hydroxide did not result in a significant improvement in fermentation performance. Based on the poor yield, it is concluded that, under the test conditions employed, this patented ethanologen does not qualify as a potential process biocatalyst for the production of fermentation fuel ethanol from corn residue hemicellulose hydrolysate prepared with dilute sulphuric acid.     

Programmable RNA Cleavage and Recognition by a Natural CRISPR-Cas9 System from Neisseria meningitidis

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Old‐growth forests buffer climate‐sensitive bird populations from warming

Aim

Habitat loss and climate change constitute two of the greatest threats to biodiversity worldwide, and theory predicts that these factors may act synergistically to affect population trajectories. Recent evidence indicates that structurally complex old‐growth forest can be cooler than other forest types during spring and summer months, thereby offering potential to buffer populations from negative effects of warming. Old growth may also have higher food and nest‐site availability for certain species, which could have disproportionate fitness benefits as species approach their thermal limits.

Location

Pacific Northwestern United States.

Methods

We predicted that negative effects of climate change on 30‐year population trends of old‐growth‐associated birds should be dampened in landscapes with high proportions of old‐growth forest. We modelled population trends from Breeding Bird Survey data for 13 species as a function of temperature change and proportion old‐growth forest.

Results

We found a significant negative effect of summer warming on only two species. However, in both of these species, this relationship between warming and population decline was not only reduced but reversed, in old‐growth‐dominated landscapes. Across all 13 species, evidence for a buffering effect of old‐growth forest increased with the degree to which species were negatively influenced by summer warming.

Main conclusions

These findings suggest that old‐growth forests may buffer the negative effects of climate change for those species that are most sensitive to temperature increases. Our study highlights a mechanism whereby management strategies to curb degradation and loss of old‐growth forests—in addition to protecting habitat—could enhance biodiversity persistence in the face of climate warming.

     

Poplar and shrub willow energy crops in the United States: field trial results from the multiyear regional feedstock partnership and yield potential maps based on the PRISM‐ELM model

To increase the understanding of poplar and willow perennial woody crops and facilitate their deployment for the production of biofuels, bioproducts, and bioenergy, there is a need for broadscale yield maps. For national analysis of woody and herbaceous crops production potential, biomass feedstock yield maps should be developed using a common framework. This study developed willow and poplar potential yield maps by combining data from a network of willow and poplar field trials and the modeling power of PRISM‐ELM. Yields of the top three willow cultivars across 17 sites ranged from 3.60 to 14.6 Mg ha^?1 yr^?1 dry weight, while the yields from 17 poplar trials ranged from 7.5 to 15.2 Mg ha^?1 yr^?1. Relationships between the environmental suitability estimates from the PRISM‐ELM model and results from field trials had an R² of 0.60 for poplar and 0.81 for willow. The resulting potential yield maps reflected the range of poplar and willow yields that have been reported in the literature. Poplar covered a larger geographic range than willow, which likely reflects the poplar breeding efforts that have occurred for many more decades using genotypes from a broader range of environments than willow. While the field trial data sets used to develop these models represent the most complete information at the time, there is a need to expand and improve the model by monitoring trials over multiple cutting cycles and across a broader range of environmental gradients. Despite some limitations, the results of these models represent a dramatic improvement in projections of potential yield of poplar and willow crops across the United States.     

Comparative phylogeography of Aedes mosquitoes and the role of past climatic change for evolution within Africa

The study of demographic processes involved in species diversification and evolution ultimately provides explanations for the complex distribution of biodiversity on earth, indicates regions important for the maintenance and generation of biodiversity, and identifies biological units important for conservation or medical consequence. African and forest biota have both received relatively little attention with regard to understanding their diversification, although one possible mechanism is that this has been driven by historical climate change. To investigate this, we implemented a standard population genetics approach along with Approximate Bayesian Computation, using sequence data from two exon‐primed intron‐crossing (EPIC) nuclear loci and mitochondrial cytochrome oxidase subunit I, to investigate the evolutionary history of five medically important and inherently forest dependent mosquito species of the genus Aedes. By testing different demographic hypotheses, we show that Aedes bromeliae and Aedes lilii fit the same model of lineage diversification, admixture, expansion, and recent population structure previously inferred for Aedes aegypti. In addition, analyses of population structure show that Aedes africanus has undergone lineage diversification and expansion while Aedes hansfordi has been impacted by population expansion within Uganda. This congruence in evolutionary history is likely to relate to historical climate‐driven habitat change within Africa during the late Pleistocene and Holocene epoch. We find differences in the population structure of mosquitoes from Tanzania and Uganda compared to Benin and Uganda which could relate to differences in the historical connectivity of forests across the continent. Our findings emphasize the importance of recent climate change in the evolution of African forest biota.