An adapter ligation-mediated PCR method for high-throughput mapping of T-DNA inserts in the Arabidopsis genome

Agrobacterium transfer DNA (T-DNA) is an effective plant mutagen that has been used to create sequence-indexed T-DNA insertion lines in Arabidopsis thaliana as a tool to study gene function. Creating T-DNA insertion lines requires a dependable method for locating the site of insertion in the genome. In this protocol, we describe an adapter ligation-mediated PCR method that we have used to screen a mutant library and identify over 150,000 T-DNA insertional mutants; the method can also be applied to map individual mutants. The procedure consists of three steps: a restriction enzyme-mediated ligation of an adapter to the genomic DNA; a PCR amplification of the T-DNA/genomic DNA junction with primers specific to the adapter and T-DNA; and sequencing of the T-DNA/genomic junction to enable mapping to the reference genome. In most cases, the sequenced genomic region extends to the T-DNA border, enabling the exact location of the insert to be identified. The entire process takes 2 weeks to complete.     

Near-field dosimetry for in vitro exposure of human cells at 60 GHz

Due to the expected mass deployment of millimeter‐wave wireless technologies, thresholds of potential millimeter‐wave‐induced biological and health effects should be carefully assessed. The main purpose of this study is to propose, optimize, and characterize a near‐field exposure configuration allowing illumination of cells in vitro at 60 GHz with power densities up to several tens of mW/cm². Positioning of a tissue culture plate containing cells has been optimized in the near‐field of a standard horn antenna operating at 60 GHz. The optimal position corresponds to the maximal mean‐to‐peak specific absorption rate (SAR) ratio over the cell monolayer, allowing the achievement of power densities up to 50 mW/cm² at least. Three complementary parameters have been determined and analyzed for the exposed cells, namely the power density, SAR, and temperature dynamics. The incident power density and SAR have been computed using the finite‐difference time‐domain (FDTD) method. The temperature dynamics at different locations inside the culture medium are measured and analyzed for various power densities. Local SAR, determined based on the initial rate of temperature rise, is in a good agreement with the computed SAR (maximal difference of 5%). For the optimized exposure setup configuration, 73% of cells are located within the ±3 dB region with respect to the average SAR. It is shown that under the considered exposure conditions, the maximal power density, local SAR, and temperature increments equal 57 mW/cm², 1.4 kW/kg, and 6 °C, respectively, for the radiated power of 425 mW. Bioelectromagnetics 33:55–64, 2012. © 2011 Wiley Periodicals, Inc.     

Cytopathic effects of the cytomegalovirus-encoded apoptosis inhibitory protein vMIA

Replication of human cytomegalovirus (CMV) requires the expression of the viral mitochondria-localized inhibitor of apoptosis (vMIA). vMIA inhibits apoptosis by recruiting Bax to mitochondria, resulting in its neutralization. We show that vMIA decreases cell size, reduces actin polymerization, and induces cell rounding. As compared with vMIA-expressing CMV, vMIA-deficient CMV, which replicates in fibroblasts expressing the adenoviral apoptosis suppressor E1B19K, induces less cytopathic effects. These vMIA effects can be separated from its cell death-inhibitory function because vMIA modulates cellular morphology in Bax-deficient cells. Expression of vMIA coincided with a reduction in the cellular adenosine triphosphate (ATP) level. vMIA selectively inhibited one component of the ATP synthasome, namely, the mitochondrial phosphate carrier. Exposure of cells to inhibitors of oxidative phosphorylation produced similar effects, such as an ATP level reduced by 30%, smaller cell size, and deficient actin polymerization. Similarly, knockdown of the phosphate carrier reduced cell size. Our data suggest that the cytopathic effect of CMV can be explained by vMIA effects on mitochondrial bioenergetics.     

Purification and physico-chemical characterisation of genetically modified phytases expressed in Aspergillus awamori

Two heterologous phytases from Aspergillus awamori and Aspergillus fumigatus obtained from submerged cultures of genetically modified fungal strains in addition to two commercially available phytase preparations (Allzyme and Natuphos phytases) were purified to homogeneity using a combination of ultrafiltration, gel filtration and ion exchange. The purified preparations were used in subsequent characterisation studies, in which Western Immunoblot analysis, pH and temperature optima, thermal stability and substrate specificity were assessed. A. fumigatus phyA phytase expressed in A. awamori exhibited activity over a broad pH range together with an increased temperature optimum, and slightly enhanced thermal stability compared to the other phytases tested, and is thus a promising candidate for animal feed applications. This particular phytase retains activity over a wide range of pH values characteristic of the digestive tract and could conceivably be more suited to the increasingly higher feed processing temperatures being utilised today, than the corresponding phytases from Aspergillus niger.     

Insight into early events in the aggregation of the prion protein on lipid membranes

The key molecular event underlying prion diseases is the conversion of the monomeric and α-helical cellular form of the prion protein (PrP^C) to the disease-associated state, which is aggregated and rich in β-sheet (PrP^Sc). The molecular details associated with the conversion of PrP^C into PrP^Sc are not fully understood. The prion protein is attached to the cell membrane via a GPI lipid anchor and evidence suggests that the lipid environment plays an important role in prion conversion and propagation. We have previously shown that the interaction of the prion protein with anionic lipid membranes induces β-sheet structure and promotes prion aggregation, whereas zwitterionic membranes stabilize the α-helical form of the protein. Here, we report on the interaction of recombinant sheep prion protein with planar lipid membranes in real-time, using dual polarization interferometry (DPI). Using this technique, the simultaneous evaluation of multiple physical properties of PrP layers on membranes was achieved. The deposition of prion on membranes of POPC and POPC/POPS mixtures was studied. The properties of the resulting protein layers were found to depend on the lipid composition of the membranes. Denser and thicker protein deposits formed on lipid membranes containing POPS compared to those formed on POPC. DPI thus provides a further insight on the organization of PrP at the surface of lipid membranes.     

A complex genetic network involving a broad-spectrum locus and strain-specific loci controls resistance to different pathotypes of Aphanomyces euteiches in Medicago truncatula

A higher understanding of genetic and genomic bases of partial resistance in plants and their diversity regarding pathogen variability is required for a more durable management of resistance genetic factors in sustainable cropping systems. In this study, we investigated the diversity of genetic factors involved in partial resistance to Aphanomyces euteiches, a very damaging pathogen on pea and alfalfa, in Medicago truncatula. A mapping population of 178 recombinant inbred lines, from the cross F83005.5 (susceptible) and DZA045.5 (resistant), was used to identify quantitative trait loci for resistance to four A. euteiches reference strains belonging to the four main pathotypes currently known on pea and alfalfa. A major broad-spectrum genomic region, previously named AER1, was localized to a reduced 440 kb interval on chromosome 3 and was involved in complete or partial resistance, depending on the A. euteiches strain. We also identified 21 additive and/or epistatic genomic regions specific to one or two strains, several of them being anchored to the M. truncatula physical map. These results show that, in M. truncatula, a complex network of genetic loci controls partial resistance to different pea and alfalfa pathotypes of A. euteiches, suggesting a diversity of molecular mechanisms underlying partial resistance.