Fluorescent microplate-based analysis of protein-DNA interactions II:immobilized DNA

A simple protein-DNA interaction analysis has been developed using both a high-affinity/high-specificity zinc finger protein and a low-specificity zinc finger protein with nonspecific DNA binding capability. The latter protein is designed to mimic background binding by proteins generated in randomized or shuffled gene libraries. In essence, DNA is immobilized onto the surface of microplate wells via streptavidin capture, and green fluorescent protein (GFP)-labeled protein is added in solution as part of a crude cell lysate or protein mixture. After incubation and washing, bound protein is detected in a standard microplate reader. The minimum sensitivity of the assay is approximately 0.4 nM protein. The assay format is ideally suited to investigate the interactions of DNA binding proteins from within crude cell extracts and/or mixtures of proteins that may be encountered in protein libraries generated by codon randomization or gene shuffling.

Evaluation of DNA enzymes targeted against the RNA component of human telomerase

Glioblastoma Multiforme (GBM) is a highly malignant form of brain cancer for which there is currently no effective cure. Consequently, developing new therapies and elucidating effective targets is crucial for this fatal disease. In recent years, DNA enzymes, deoxyribonucleic acid molecules with enzymatic activity, have emerged. In the same manner as ribozymes, DNA enzymes are able to effect cleavage of RNA in a sequence-specific manner, and operate with catalytic efficiency. In this study, two DNA enzymes were designed to target the template region of human telomerase RNA (hTR), utilising the 10-23 and 8-17 catalytic motifs elucidated by Santoro and Joyce (1997). Telomerase is an RNA-dependent DNA polymerase, which stabilises telomere lengths by adding hexameric repeats (TTAGGG in humans) to chromosome termini, thus preventing the telomere shortening that usually occurs during mitotic cell division. Telomerase activity, whilst absent in normal somatic tissues, is present in almost 90% of all tumours. Thus, there is speculation that telomerase may be the much sought universal target for therapeutic intervention in cancer. In vitro cleavage assays showed both DNA enzymes to be catalytically competent. Unmodified phosphodiester (PO) backbone DNA enzymes were rapidly degraded in the presence of serum, with a half-life of 10 minutes. The common approach of introducing phosphorothioate (PS) linkages was used in an effort to overcome this instability. As a result of concurrent activity and stability studies on the DNA enzymes with various numbers of PS linkages, the DNA enzymes with a PO core and PS arms were chosen for use in further cell work. The cleavage activity of both was shown to be specific and affected by temperature, pH, MgCI2 concentration and enzyme concentration. Both DNA enzyme motifs reduced telomerase activity in cell lysates, as assessed by the telomerase repeat amplification protocol (TRAP) with an IC50 of 100nM. DNA enzymes being polyanionic molecules do not readily cross biological barriers. Cellular association of naked DNA enzyme was inefficient at less than 2%. Cellular delivery of the DNA enzymes was effectively improved using commercial cationic lipid formulations. However, the lipid-mediated delivery of DNA enzymes to U87-MG cells over a 4-hour period did not significantly inhibit cell proliferation compared to controls. This is possibly due to an expected lag period between the inhibition of telomere maintenance and cell death. Therefore, biodegradable polymer microspheres were investigated as a potential delivery option for prolonged and sustained delivery. In vitro release profiles showed that after an initial burst, sustained release of DNA enzymes was observed over 35 days. Finally, the efficacy and specificity of the DNA enzymes were demonstrated in a luciferase based reporter assay. Specific inhibition of luciferase expression was displayed at 10nM. Thus DNA enzymes have potential against endogenous cellular targets.

An outbreak of Serratia marcescens on the neonatal unit:a tale of two clones

Serratia spp. are an important cause of hospital-acquired infections and outbreaks in high-risk settings. Twenty-one patients were infected or colonized over a nine-month period during 2001-2002 on a neonatal unit. Twenty-two isolates collected were examined for antibiotic susceptibility, β-lactamase production and genotype. Random-amplified polymorphic DNA polymerase chain reaction and pulsed-field gel electrophoresis revealed that two clones were present. The first clone caused invasive clinical infection in four babies, and was subsequently replaced by a non-invasive clone that affected 14 babies. Phenotypically, the two strains also differed in their prodigiosin production; the first strain was non-pigmented whereas the second strain displayed pink-red pigmentation. Clinical features suggested a difference in their pathogenicity. No environmental source was found. The outbreak terminated following enhanced compliance with infection control measures and a change of antibiotic policy. Although S. marcescens continued to be isolated occasionally for another five months of follow-up, these were sporadic isolates with distinct molecular typing patterns. © 2005 The Hospital Infection Society.

Studies on the mode of cytotoxicity of imidazotetraziones

The irnidazotetrazinones are a novel group of anti tumour agents which have demonstrated good activity against a range of murine tumours and human xenografts. They possess a structure activity relationship similar to the anti tumour triazenes, with the chloroethyl (mitozolomide) and methyl (temozolomide) analogues being active antitumour agents, whilst the ethyl (CCRG 82019) and higher homologues are inactive. This thesiS attempts to elucidate the biological mechanisms responsible for the strict structure-activity relationship observed amongst the imidazotetrazinones. Mitozolomide is the only agent chemically capable of cross-linking DNA , which has been suggested to be responsible fo r the cytotoxicity of this group of agents. Only mitozolomide and ternozolornide Exhibit a marked ditferential toxicity towards the 0 -alkylguanine-DNA alkyltransferase deficient GM892A (Mer-) cell line rather than the proficient Raji cell line (Mer+). The rate of uptake of imidazotetrazinones into cells is similar for all three agents in both cell lines, and does not explain the differing sensitivities to these agents. The effect of drug treatment on the incorporation of precursors into macromolecules, and their pool sizes, was examined. Temozolomide administration was found to alter de novo protein synthesis in both GM892A and Raji cells. Flow cytometric analysis revealed that temozolomide and CCRG 82019 block cells in late S/G2/M phase of the cell cycle , similar to that observed with mitozolomide. The extent of reaction of all three drugs with isolated macromolecules and cellular macromolecules was determined, and differences found, with cellular repair processes influencing the number of alkyl lesions remaining bound to macromolecules. The specific bases formed in calf thymus DNA after treatment with either temozolornide and CCRG 82019 was measured, and it was found that the types and relative amounts of lesions formed, differed, as well as the total level of alkylation. Whereas DNA extracted from imidazotetrazinone treated cells is not affected in its ability to support RNA polymerase activity, an effect is observed on the ability to extract DNA polymerase from drug treated cells. This may suggest that the alkylated DNA must be in intact chromatin for the lesion to manifest its effects. Temozolomide and methyl methanesulphonate do got appear to act with a synergistic mode of action. The 0 -position of guanine is suspected to be a critical site for the action of these types of drugs.