Halting a computer or biological virus outbreak requires a detailed understanding of the timing of the interactions between susceptible and infected individuals. While current spreading models assume that users interact uniformly in time, following a Poisson process, a series of recent measurements indicates that the intercontact time distribution is heavy tailed, corresponding to a temporally inhomogeneous bursty contact process. Here we show that the non-Poisson nature of the contact dynamics results in prevalence decay times significantly larger than predicted by the standard Poisson process based models. Our predictions are in agreement with the detailed time resolved prevalence data of computer viruses, which, according to virus bulletins, show a decay time close to a year, in contrast with the 1 day decay predicted by the standard Poisson process based models.
Depending on their origin, sedimentary phosphate
rocks (PRs) may differ in their P solubility, and, as a consequence, in their
agronomic effectiveness. The effect of six phosphate rocks (PR) - originating
from Algeria (ALG), North Florida (FLO), North Carolina (NCA), Senegal (SEN)
Morocco (MOR) and Hyperphosphate (HYP) with various P solubility (evaluated by
2% formic acid, 2% citric acid, and neutral ammonium citrate) - as well as
single superphosphate (SSP) and superphosphate + lime (SSP + Ca) (each P source
on 4 P levels, with doses of 0, 100, 400 and 1600 mg P
2
O
5
·kg
-1
soil) on the shoot yield of tillering stage spring barley, soil available
P (i.e. H
2
O, Olsen, Bray1, Lakanen-Erviö (LE) and ammonium lactate
(AL) extractable P contents) were studied in pot experiments set up with acidic
sandy soil (Nyírlugos, Hungary) and acidic clay loam soil (Ragály, Hungary),
both with low P supplies. The average
spring barley shoot yield at the beginning of shooting was 95% higher on the
colloid-rich acidic (pH
KCl
: 4.5) clay loam soil than on the
colloid-poor acidic (pH
KCl
: 3.8) sandy soil. The differences in the
solubility of phosphate rocks showed close correlation to the differences in P
responses. On both soils, the correlation between total PR-P added and P
responses in spring barley shoot yield was much weaker than that between
neutral ammonium citrate soluble PR-P added and P responses in spring barley
shoot yield. When phosphate rocks were applied as P sources, the comparison of
soil test P methods showed a different picture on the two soils. In the case of
the acidic sandy soil (Nyírlugos), the strongly acid LE-P (r² = 0.83) and
AL-P (r² =0.74) tests gave the highest correlation coefficients with
spring barley responses to P, while on the acidic clay loam soil (Ragály) these
were achieved by the Olsen-P (r² = 0.88) and Bray1-P (r² =0.88)
methods.
Biotic and abiotic stress effects can limit the productivity of plants to great extent. In Hungary, drought is one of the most important constrains of biomass production, even at the present climatic conditions. The climate change scenarios, developed for the Carpathian basin for the nearest future predict further decrease in surface water resources. Consequently, it is essential to develop drought stress tolerant wheat genotypes to ensure sustainable and productive wheat production under changed climate conditions. The aim of the present study was to compare the stress tolerance of two winter wheat genotypes at two different scales. Soil water regime and development of plants, grown in a pot experiment and in large undisturbed soil columns were evaluated. The pot experiments were carried out in a climatic room in three replicates. GK Élet wheat genotype was planted in six, and Mv Emese in other six pots. Two pots were left without plant for evaporation studies. Based on the mass of the soil columns without plant the evaporation from the bare soil surface was calculated in order to distinguish the evaporation and the transpiration with appropriate precision. A complex stress diagnosis system was developed to monitor the water balance elements. ECH<sub>2</sub>O type capacitive soil moisture probes were installed in each of the pots to perform soil water content measurements four times a day. The irrigation demand was determined according to the hydrolimits, derived from soil hydrophysical properties. In case of both genotypes three plants were provided with the optimum water supply, while the other three ones were drought-stressed. In the undisturbed soil columns, the same wheat genotypes were sawn in one replicate. Similar watering strategy was applied. TDR soil moisture probes were installed in the soil at various depths to monitor changes in soil water content. In order to study the drought stress reaction of the wheat plants, microsensors of 1.6 mm diameter were implanted into the stems and connected to a quadrupole mass spectrometer for gas analysis. The stress status was indicated in the plants grown on partly non-irrigated soil columns by the lower CO<sub>2</sub> level at both genotypes. It was concluded that the developed stress diagnosis system could be used for soil water balance elements calculations. This enables more precise estimation of plant water consumption in order to evaluate the drought sensitivity of different wheat genotypes.
Human serum albumin (HSA) is the most abundant plasma protein in circulation. The three most important drug-binding sites on HSA are Sudlow’s Site I (subdomain IIA), Sudlow’s Site II (subdomain IIIA), and Heme site (subdomain IB). Heme site and Site I are allosterically coupled; therefore, their ligands may be able to allosterically modulate the binding affinity of each other. In this study, the effects of four Heme site ligands (bilirubin, biliverdin, hemin, and methyl orange) on the interaction of the Site I ligand warfarin with HSA were tested, employing fluorescence spectroscopic, ultrafiltration, and ultracentrifugation studies. Our major results/conclusions are the following. (1) Quenching studies indicated no relevant interaction, while the other fluorescent model used suggested that each Heme site ligand strongly decreases the albumin binding of warfarin. (2) Ultrafiltration and ultracentrifugation studies demonstrated the complex modulation of warfarin–HSA interaction by the different Heme site markers; for example, bilirubin strongly decreased while methyl orange considerably increased the bound fraction of warfarin. (3) Fluorescence spectroscopic studies showed misleading results in these diligand–albumin interactions. (4) Different Heme site ligands can increase or decrease the albumin binding of warfarin and the outcome can even be concentration dependent (e.g., biliverdin and hemin).
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