Enhancement of photosynthetic O2 evolution in Chlorella vulgaris under high light and increased CO2 concentration as a sign of acclimation to phosphate deficiency.

The photosynthetic oxygen evolution of Chlorella vulgaris (Beijer.) cells taken from phosphate-deficient (-P) and control cultures was measured during 8 days of culture growth. Under inorganic carbon concentration (50 microM) in the measuring cell suspension and irradiance (150 micromol m(-2) s(-1)), the same as during culture growth, there were no marked differences in the photosynthetic O2 evolution rate between the -P cells and the controls. The much slower growth of -P cultures indicated that the utilization of absorbed photosynthetically active radiation (PAR) in the CO2 assimilation and biomass production were in -P cells less efficient than in the controls. Alga cells under the phosphorus stress utilized more of the absorbed PAR in the nitrate reduction than the control cells. However, under conditions of more efficient CO2 supply (inorganic carbon concentration 150 microM, introducing of exogenous carbonic anhydrase to the measuring cell suspension) and under increased irradiance (500 micromol m(-2) s(-1)), the photosynthetic O2 evolution in -P cells reached a higher rate than in the controls. The results suggest that in -P cells the restricted CO2 availability limits the total photosynthetic process. But under conditions more favorable for the CO2 uptake and under high irradiance, the -P cells may reveal a higher photosynthetic oxygen evolution rate than the controls. It is concluded that an increased potential activity of the photosynthetic light energy absorption and conversion in the C. vulgaris cells from -P cultures is a sign of acclimation to phosphorus stress by a sun-type like adaptation response of the photosynthetic apparatus.     

Natural occurrence of Bacillus thuringiensis and Bacillus cereus in eukaryotic organisms: a case for symbiosis

Bacillus thuringiensis and Bacillus cereus, two members of the Bacillus cereus sensu lato group, are most noted for their virulence in, respectively, arthropods and mammals including humans. Because of their pathogenicity to insects in particular, and their narrow host range, strains of B. thuringiensis have been utilised successfully as biocontrol agents of insect pests. Whereas B. cereus is not an established entomopathogen, certain strains of this species are well known to be etiological agents of gastrointestinal and emetic syndromes in humans. While much is known about the taxonomic properties and molecular basis for virulence of B. thuringiensis and B. cereus, comparatively less is known about their ecology in natural environments. Thus, there are limited data regarding their resilience, i.e. recycling of vegetative and sporulated phases of growth in soil, ecolgical niches including symbiotic interactions with other organisms, and the impact on ecosystems in which they proliferate. Nevertheless, based on recent data, a picture is beginning to emerge that B. thuringiensis and B. cereus are capable of establishing mutual and commensal relationships with both animals and plants. In this regard, these bacilli can proliferate in the digestive tracts of animals, where upon defecation they form dormant spores in the soil, and to a lesser extent on the phylloplane and rhizospheres of plants. Altogether, current evidence strongly suggests that B. thuringiensis and B. cereus are capable of completing their life cycles and recycling through various reservoirs, including animals, plants, and soil. This review focuses on the current knowledge pertaining to the ecologic interactions between B. thuringiensis and B. cereus and eukaryotic hosts, with special emphasis on symbiosis.     

Multidrug resistance in fungi

Antibiotic and synthetic chemotherapeutic resistance in pathogenic yeast becomes one of the biggest challenges for the modern chemotherapy. An increasing number of pathogenic yeast and filamentous fungi resistant to the action of the majority of currently used drugs is isolated in clinics nowadays. Among variety of the resistance mechanisms, the most dangerous grows to be the multidrug resistance. The most important mechanism of the multidrug resistance is the overexpression of membrane proteins participating in the active efflux of drugs out of the cells subjected to chemotherapy. Representatives of two classes of multidrug efflux transporters, ABC and MFS, have been identified in fungi. One of the most important strategies for overcome the phenomenon of multidrug resistance in pathogenic fungi, is the use of chemical compounds co-administrated with chemotherapeutics which are able to restore drug susceptibility in multidrug resistant cells. Mode of action of these chemical compounds may be very diverse, from the substrate competition, through the influence on the membrane fluidity, to the multidrug transporters activity modulation. This paper presents a review of the current knowledge on proteins contributing to fungal multidrug resistance and strategies for overcoming multidrug resistance by pharmacological intervention.     

Contribution of the mevalonate and methylerythritol phosphate pathways to the biosynthesis of dolichols in plants

Plant isoprenoids are derived from two biosynthetic pathways, the cytoplasmic mevalonate (MVA) and the plastidial methylerythritol phosphate (MEP) pathway. In this study their respective contributions toward formation of dolichols in Coluria geoides hairy root culture were estimated using in vivo labeling with (13)C-labeled glucose as a general precursor. NMR and mass spectrometry showed that both the MVA and MEP pathways were the sources of isopentenyl diphosphate incorporated into polyisoprenoid chains. The involvement of the MEP pathway was found to be substantial at the initiation stage of dolichol chain synthesis, but it was virtually nil at the terminal steps; statistically, 6-8 isoprene units within the dolichol molecule (i.e. 40-50% of the total) were derived from the MEP pathway. These results were further verified by incorporation of [5-(2)H]mevalonate or [5,5-(2)H(2)]deoxyxylulose into dolichols as well as by the observed decreased accumulation of dolichols upon treatment with mevinolin or fosmidomycin, selective inhibitors of either pathway. The presented data indicate that the synthesis of dolichols in C. geoides roots involves a continuous exchange of intermediates between the MVA and MEP pathways. According to our model, oligoprenyl diphosphate chains of a length not exceeding 13 isoprene units are synthesized in plastids from isopentenyl diphosphate derived from both the MEP and MVA pathways, and then are completed in the cytoplasm with several units derived solely from the MVA pathway. This study also illustrates an innovative application of mass spectrometry for qualitative and quantitative evaluation of the contribution of individual metabolic pathways to the biosynthesis of natural products.     

Virulence factor of potato virus Y, genome-attached terminal protein VPg, is a highly disordered protein

Potato virus Y (PVY) is a common potyvirus of agricultural importance, belonging to the picornavirus superfamily of RNA plus-stranded viruses. A covalently linked virus-encoded protein VPg required for virus infectivity is situated at the 5' end of potyvirus RNA. VPg seems to be involved in multiple interactions, both with other viral products and host proteins. VPgs of potyviruses have no known homologs, and there is no atomic structure available. To understand the molecular basis of VPg multifunctionality, we have analyzed structural features of VPg from PVY using structure prediction programs, functional assays, and biochemical and biophysical analyses. Structure predictions suggest that VPg exists in a natively unfolded conformation. In contrast with ordered proteins, PVY VPg is not denatured by elevated temperatures, has sedimentation values incompatible with a compact globular form, and shows a CD spectrum of a highly disordered protein, and HET-HETSOFAST NMR analysis suggests the presence of large unstructured regions. Although VPg has a propensity to form dimers, no functional differences were seen between the monomer and dimer. These data strongly suggest that the VPg of PVY should be classified among intrinsically disordered proteins. Intrinsic disorder lies at the basis of VPg multifunctionality, which is necessary for virus survival in the host.