r these test stains. The next phase of our research will focus on confirming these in vitro observations using analogous in vivo Virulence Potential of Acinetobacter Strains murine exposure scenarios as recently reported for screening Bacillus organisms.
Drought is likely the most PubMed ID:http://www.ncbi.nlm.nih.gov/pubmed/22189364 important environmental factor that adversely affects plant growth and development. Effects of drought on plants have been studied for a long time and changes induced by insufficient water supply have been examined from the whole plant/plant population level to biochemical and molecular level. The primary and the most rapidly developing symptom of water stress in plants is a cessation of cell expansion caused by a decrease of turgor. This reduces plant water use but negatively affects growth and development together with the reduction or suppression of cell division which is, however, much less sensitive to water deficit compared to cell expansion. Decrease of transpiration caused by partial or complete stomatal closure is associated with changes in both leaf water status and soil moisture content, the latter being mediated predominantly through signalling molecules produced by dehydrating roots, particularly the abscisic acid. A dependence of stomatal behaviour on air humidity and hydraulic conductivity of xylem was also found. The sensitivity of stomata to ABA can be regulated by additional factors like xylem sap pH, plant nutritional status, etc. The complex interplay between ABA and other growth regulators in the induction of stomatal closure is far from being fully understood despite recent progress in this area. The closure of stomata naturally affects more Eglumetad chemical information processes than just transpiration: the limitation of CO2 uptake by leaves is closely linked to the stomatal control of water loss. The reduction in net carbon assimilation/photosynthetic rate and the decrease of intercellular CO2 concentration are thus usually regarded as another early symptoms of water stress. In the initial stages of water deficit, the reductive effect of stomatal closure on transpiration rate is greater than the effect on CO2 assimilation, but with further development of water deficit, both processes are often dramatically reduced. Actual contribution of the decrease in stomatal conductance and ci to drought-induced limitation of Drought Tolerance in Maize ways and other important cellular processes. The quantities and functions of these proteins are regulated not only by the amounts of their mRNAs but also at the translational and post-translational levels and various discrepancies have been found between the amounts of transcripts and their respective proteins in droughtstressed plants. The analysis of the plant proteome thus offers several advantages over transcriptomic methods for the large-scale study of the molecular changes associated with the drought stress response. Proteomics has already been used to evaluate drought-responsive proteins in the leaves of important crop species, such as rice, maize, wheat, cotton, peanut, amaranth, alfalfa, sugar beet and sunflower. The simplest studies focused only on the dehydration-induced qualitative and quantitative changes of proteins. Several authors also compared the responses of tolerant and sensitive genotypes of a single species to drought conditions. Such analyses can be very useful in revealing proteins that are directly involved in the mechanisms underlying plant tolerance to drought. These proteins can then serve as molecula