Subcellular localization of HCV core protein regulates its ability for p53 activation and p21 suppression

An internal RNA standard proved less suitable in bacterial gene expression experiments. We therefore developed a method for simultaneous RNA and gDNA (genomic DNA) isolation from in vitro and in vivo samples containing staphylococci and combined it with quantitative PCR. The reliability of gDNA for bacterial quantification and for standardisation in gene expression experiments was evaluated. Quantitative PCR proves equivalent to quantitative culture for in vitro samples, and superior for in vivo samples. In gene expression experiments, gDNA permits a good standardisation for the initial amount of bacteria. The average interassay variability of the in vitro expression is 20.1%. The in vivo intersample variability was 73.3%. This higher variability can be attributed to the biological variation of gene expression in vivo. This method permits exact quantification of the number of bacteria and the expression of genes in staphylococci in vivo (e.g., in biofilms, evolution in time) and in vitro.     

RNA Amplification in Brain Tissues

Recent developments in gene array technologies, specifically cDNA microarray platforms, have made it easier to try to understand the constellation of gene alterations that occur within the CNS. Unlike an organ that is comprised of one principal cell type, the brain contains a multiplicity of both neuronal (e.g., pyramidal neurons, interneurons, and others) and noneuronal (e.g., astrocytes, microglia, oligodendrocytes, and others) populations of cells. An emerging goal of modern molecular neuroscience is to sample gene expression from similar cell types within a defined region without potential contamination by expression profiles of adjacent neuronal subtypes and noneuronal cells. At present, an optimal methodology to assess gene expression is to evaluate single cells, either identified physiologically in living preparations, or by immunocytochemical or histochemical procedures in fixed cells in vitro or in vivo. Unfortunately, the quantity of RNA harvested from a single cell is not sufficient for standard RNA extraction methods. Therefore, exponential polymerase-chain reaction (PCR) based analyses and linear RNA amplifications, including a newly developed terminal continuation (TC) RNA amplification methodology, have been used in combination with single cell microdissection procedures to enable the use of cDNA microarray analysis within individual populations of cells obtained from postmortem brain samples as well as the brains of animal models of neurodegeneration.     

Membrane-assisted culture of fungal mycelium on agar plates for RNA extraction and pharmacological analyses

Fungal mycelium grown in liquid culture is easy to harvest for RNA extraction and gene expression analyses, but liquid cultures often develop rather heterogeneously. In contrast, growth of fungal mycelium on agar plates is highly reproducible. However, this biological material cannot be harvested easily for downstream analyses. This article describes a PVDF (polyvinylidene difluoride) membrane-assisted agar plate culture method that enables the harvest of mycelium grown on agar plates. This culture method leads to a strongly reduced variation in gene expression between biological replicates and requires less growth space as compared with liquid cultures.     

RNA isolation from yeast using silica matrices.

RNA isolation from yeast is complicated by the need to initially break the cell wall. While this can be accomplished by glass bead disruption or enzyme treatment, these approaches result in DNA contamination and/or the need for incubation periods. We have developed a protocol for the isolation of RNA samples from yeast that minimizes degradation by RNases and incorporates two purification steps: acid phenol extraction and binding to a silica matrix. The procedure requires no precipitation steps, facilitating automation, and can be completed in less than 90 min. The RNA quality is ideal for microarray analysis.     

Drosophila U6 promoter-driven short hairpin RNAs effectively induce RNA interference in Schneider 2 cells

The effect of RNA interference (RNAi) is generally more potent in Drosophila Schneider 2 (S2) cells than in mammalian cells. In mammalian cells, PolIII promoter-based DNA vectors can be used to express small interfering RNA (siRNA) or short hairpin RNA (shRNA); however, this has not been demonstrated in cultured Drosophila cells. Here we show that shRNAs transcribed from the Drosophila U6 promoter can efficiently trigger gene silencing in S2 cells. By targeting firefly luciferase mRNA, we assessed the efficacy of the shRNAs and examined the structural requirements for highly effective shRNAs. The silencing effect was dependent on the length of the stem region and the sequence of the loop region. Furthermore, we demonstrate that the expression of the endogenous cyclin E protein can be repressed by the U6 promoter-driven shRNAs. Drosophila U6 promoter-based shRNA expression systems may permit stable gene silencing in S2 cells.     

Quantification of Escherichia coli genomic DNA contamination in recombinant protein preparations by polymerase chain reaction and affinity-based collection

This study describes the development of a novel assay for the quantification of Escherichia coli genomic DNA contamination in recombinant protein samples. The technique is based on PCR amplification and digoxygenin labeling of the genes encoding 5S ribosomal RNA followed by affinity-based collection and detection. Samples containing 1 pg x mL(-1) of extracted E. coli genomic DNA (gDNA) could be measured using this method. Using extracted E. coli gDNA as standards, a 35-cycle PCR reaction exhibited a linear response versus template concentration between 1 pg x mL(-1) and1 ng x mL(-1) genomic DNA even when diluted in a variety of buffering conditions. Comparison of the novel assay with a traditional filter binding and hybridization technique using recombinant protein samples confirmed that the procedure was accurate and sensitive. The assay described in this report is a safer and less expensive alternative to radioactive techniques employed for DNA quantification, utilizing readily available reagents and apparatus.     

Use of a simple method to isolate intact RNA from partially hydratedSelaginella lepidophylla plants

Isolation of high-quality RNA is a necessary step in gene expression analysis. Although many methods can be used to isolate RNA from plants where contamination of preparations with complex carbohydrates or phenolic compounds is a problem, the application of these methods toSelaginella lepidophylla tissues has failed to obtain good-quality RNA. Here we introduce 2 modifications to the method developed by Chomczynski and Sacchi (1987), generating a simple and rapid method that allows the isolation of intact RNA fromS. lepidophylla-dehydrated tissues. Although the introduced modifications are not new, their addition proved to be decisive for success in RNA isolation. Quality of the RNA obtained was evaluated by electrophoresis in agarose and by 3 different PCR-based techniques—RT-PCR, RNA differential display, and synthesis of a cDNA library.     

Imprinting of the murine MAS protooncogene is restricted to its antisense RNA.

The Mas protooncogene encodes a G protein-coupled receptor with the common seven transmembrane domains and may be involved in the actions of angiotensins. The gene is located in close proximity to the paternally imprinted Igf2r gene and its maternal imprinting has been reported but remained controversial. We used mice carrying a targeted deletion of the Mas protooncogene on the maternal or paternal chromosome to clarify this issue. In all Mas-expressing organs of adult mice such as heart, kidney, testis or brain, no Mas mRNA was missing in heterozygous animals inheriting the deleted allele from the father excluding mono-allelic paternal expression. However, we show exclusive paternal expression of a Mas antisense RNA, confirming the maternal imprinting of this antisense RNA in all investigated adult tissues and in embryos. Our results strongly suggest that Mas is not imprinted in mice but that an antisense RNA probably starting in the neighboring Igf2r gene is maternally imprinted in both embryos and adult organs.