Rapid and specific detection of RNA base sequence using fluorescence polarization.

Rapid and specific determination of the RNA gene of hepatitis C virus (HCV), which had been multiplied by NASBA, was performed using a fluorescence polarization assay. The polarization of the probe DNA in the presence of HCV positive sample, amplified by NASBA, was obviously different from those in the presence of negative control samples. The total time for the gene amplification and detection was about 90 min, while the polarization detection was completed within 10 min. The slight increase of polarization was also confirmed with the hybridization between probe oligo-DNA 25-mers and the synthesized complementary oligo-RNA 25-mers. The polarization of positive and negative samples showed excellent agreement with the results obtained from electrophoresis and dot-blot hybridization.     

Polyethylene glycol derivatives of base and sequence specific DNA ligands: DNA interaction and application for base specific separation of DNA fragments by gel electrophoresis.

Various base pair specific DNA ligands comprising a phenyl phenazinium dye, a triphenylmethan dye and Hoechst 33258 were covalently bound to polyethylene glycol (PEG) via ester or ether bonds. The DNA interactions of the PEG derivatives formed were shown to exhibit the same base pair specificity as the parent compounds. Since the PEG chains thus bound to the DNA could be expected to increase drastically the frictional coefficient of the DNA, the PEG derivatives were used for base specific DNA separations in agarose and polyacrylamide gel electrophoresis. The procedures, which do not require any special techniques, are described in detail. The resolution observed in agarose gels allows one to separate equally sized DNA fragments differing as little as 1% in base composition at mean travel distances of about 10 cm. Examples of gels showing the base compositional heterogeneity of restriction fragments obtained from lambda DNA, E. coli DNA and calf thymus DNA are given.     

Selective cleavage of closely-related mRNAs by synthetic ribozymes.

In Phaseolus vulgaris L. (French bean) glutamine synthetase (GS) is encoded by four closely-related genes termed gln-alpha, gln-beta, gln-gamma and gln-delta. We have constructed and characterised in vitro a number of hammerhead ribozymes designed to cleave individual RNAs encoded by these genes. The three ribozymes, termed J1, J2 and J3, were targeted to cleave RNA at the start of the gamma and beta, and the middle of the gamma, GS open reading frames respectively. All three ribozymes successfully discriminated between the four (alpha, beta, gamma and delta) highly homologous sequences, even though the targeted sites of cleavage shared up to 18 out of 22 identical bases with other gene family members. The ribozyme-mediated cleavage reactions were Mg2+ dependent and enhanced at higher temperatures, although the J1 ribozyme retained considerable activity at physiological temperatures. Both J1 and J2 demonstrated a time-dependent cleavage of their targeted GS RNAs, although these two ribozymes differed markedly in their ability to cleave multiple substrate molecules. The rate of cleavage by J1 was found to be reduced in the presence of related GS RNAs and by total leaf poly(A) RNAs. The implications of these results for ribozyme activity in vivo are discussed.     

CpG methylation recruits sequence specific transcription factors essential for tissue specific gene expression

CG methylation is an epigenetically inherited chemical modification of DNA found in plants and animals. In mammals it is essential for accurate regulation of gene expression and normal development. Mammalian genomes are depleted for the CG dinucleotide, a result of the chemical deamination of methyl-cytosine in CG resulting in TpG. Most CG dinucleotides are methylated, but ~ 15% are unmethylated. Five percent of CGs cluster into ~ 20,000 regions termed CG islands (CGI) which are generally unmethylated. About half of CGIs are associated with housekeeping genes. In contrast, the gene body, repeats and transposable elements in which CGs are generally methylated. Unraveling the epigenetic machinery operating in normal cells is important for understanding the epigenetic aberrations that are involved in human diseases including cancer. With the advent of high-throughput sequencing technologies, it is possible to identify the CG methylation status of all 30 million unique CGs in the human genome, and monitor differences in distinct cell types during differentiation and development. Here we summarize the present understanding of DNA methylation in normal cells and discuss recent observations that CG methylation can have an effect on tissue specific gene expression. We also discuss how aberrant CG methylation can lead to cancer. This article is part of a Special Issue entitled: Chromatin in time and space.